A little over a year ago, when the FSU Coastal & Marine Laboratory and WFSU-TV – a TV station – started this online enterprise, the understanding was that at some point this would end up being a show. And so here we are. As you may have gathered from that video up there, this will be about predators and prey: who’s eating whom, and who’s scaring whom. We will of course be doing this through the prism of David and Randall’s studies: the consumptive and non-consumptive effects of predators in salt marshes and oyster reefs, and the methods used to shine a light on these interactions. Continue reading →
Emily holds a net that will soon be full of marsh bugs. Later, at the lab, she will identify the many insect species that live amongst fiddlers and periwinkles, species more often associated with the habitat.
Several weeks ago, I went to Houston to meet Thomas Decker, a tech in Steve Pennings’ lab at the University of Houston. Thomas graciously offered up his time to help me with my insect identifications. I have absolutely zero background in entomology, the study of bugs and other creepy crawlies most people squirm about. So how did I end up spending hours puzzling through an identification book on insects, a book with so many unfamiliar terms that I was constantly flipping to the glossary and various diagrams? Silly me, I decided that I needed to include the terrestrial part of my salt marsh community. Which meant I have spent quite a bit of one-on-one time with a dichotomous key on insects. A dichotomous key is a “choose your own adventure” style guide to identification. Continue reading →
One of the most fascinating aspects of the field of science is the unpredictable patterns and directions that certain communities can take over a period of time. Whether the change in a habitat occurs due a spontaneous event such as a devastating hurricane or a longer, more gradual event such as climate change; it is important to understand the impacts these changes may have on the resident organisms as well as the future of the community. Studying how organisms respond to each other and their environment are key principles of ecology.
As David mentioned in the previous post, I have recently begun my graduate student work in St. Augustine, where I hope to gain a better understanding of the unique observations we have made while working in the area for the NSF oyster project.
Other than being the nation’s oldest city, St. Augustine is a very dynamic place. From condominiums and restaurants to historic landmarks and beautiful beaches; the area is flooded with snow-birds during this time of year. More notably, St. Augustine has countless state parks, wildlife preserves, and protected habitats; which allow for not only attractions for tourists but areas of research for scientists and most importantly, shelter and nurseries for the resident wildlife. Continue reading →
Scanning the photo, you can see crown conchs crawling about this Saint Augustine reef. Crown conchs are a normal sight on Florida reefs, but not to the extent seen here. David has tasked Hanna Garland with looking into this very localized phenomenon and its relationship with increasing reef failures.
Dr. David KimbroFSU Coastal & Marine Lab
Last week I detailed a recent trip to St. Augustine, ending the post with a mention of a side project being embarked upon by my lab there. Throughout the past year, we’ve noticed that our St. Augustine study site was loaded with tons of crown conchs. Although crown conchs are ubiquitous in Florida, they are abnormally abundant on our St. Augustine reefs and our St. Augustine reefs are mostly dead. All our other sites have relatively healthy looking oyster reefs and few crown conchs.
But a few miles north of our monitoring reefs, we find absolutely no crown conchs and the health of the oysters is great. Because crown conchs, as has been shown by the research of our very own Doc Herrnkind, love eating oysters, it’s easy to conclude that crown conchs have mowed down all the oysters on our monitoring reefs. But why are they restricted only to our monitoring reefs? Is there a predator of conchs present north of reefs but that is absent on our monitoring reefs? Perhaps the environment has changed in a way that killed all of the oysters and the crown conchs are just cleaning up the mess.
Proboscis out (protruding from the bottom of the snail), a crown conch heads towards a clump of oysters. The conch will use its proboscis to pry open the oyster shell and suck out the meat.
Luckily, Hanna has agreed to enter my lab as a graduate student to tackle this research project. So, she spent a number of days collecting coarse-scale data on the spatial extent of this conch-oyster pattern, consulting with locals about when this pattern developed, and talking with an oceanographer about how to learn whether and how the physical environment has lead to this pattern. In a forthcoming post, I’ll let Hanna fill you in on the details of this new project, which we will be implementing quickly. This is really important to the local community because our monitoring reefs and the conch infested area used to be the most productive area in St. Augustine for harvesting oysters and rearing clams. But now, aquaculture leases here have been abandoned and a very large population of crown conchs appears to have taken up residence.
Stay tuned for Hanna’s post later this week, she’ll go into a little more detail on what we’re doing.
David’s research is funded by the National Science Foundation.
On Wednesday, June 29 at 7:30 PM/ET, WFSU-TV premieres the In the Grass, On the Reef full length documentary. David and Randall guide us through the world of coastal predators (like crown conchs). Top predators maintain important ecosystems like salt marshes and oyster reefs- but the manner in which they do this may not be confined to eating prey. Tune in to find out more!
Where did my winter of catching up on work go? And why is spring quickly hurtling into summer? YIKES!
…Okay, I feel better. All of us here feel a little behind on things, because this past winter and spring have been full of other projects (in addition to the oyster one) such as investigating how the oil spill affected marshes throughout the west coast of Florida and examining what all of those snails are up to out on Bay Mouth Bar. But now that summer is almost upon us, it’s time to move all hands on deck back towards the ambitious summer oyster goals.
Environmental vs. Predator Effects.
To lay the ground work for this summer’s oyster research, I spent a few days in St. Augustine, Florida, which is where we will conduct our colossal field experiment. As a recap of the oyster objectives, we spent year 1 monitoring the oyster food web at 12 estuaries between Florida to North Carolina. Well, we found some cool patterns regarding the food web and water-filtration/ nutrient cycling services on oyster reefs (see the 2010 wrap-up). So, now we want to know what’s causing those patterns. Are differences in oyster reefs between NC to FL due purely to differences in water temperature, salinity, or food for oysters (phytoplankton)? Or, do we have a higher diversity of predators down south that are exerting more “top-down” pressure on the southern reefs? Or, is it a combination of the environment and predators? Continue reading →
It kind of looks like one of those vintage ’80’s jackets adorned with mirrors and sequins- mollusk style. This horse conch’s got a little bit of everything on it, the result of an interesting reversal of roles in this seagrass bed on Bay Mouth Bar.
When I heard it was supposed to rain on Saturday, I was a little bummed. I was planning on taking the family to the FSU Coastal and Marine Lab Open House followed by the FSU Spring Game (where my 12-week old son could attend his first football game featuring my two favorite teams). Luckily, the storms rolled through early in the morning and made for a nice day at the coast.
I started off by visiting my friends at the Randall Hughes and David Kimbro labs. Robyn and Emily held down the fort in the Hughes lab, where kids watched a very peculiar sport. As Randall’s previous post promised, there were indeed periwinkle snail races. As you can see from the photo at the right here, the snails were color coded (white and blue) and numbered so that they could be told apart. Some crown conchs (periwinkle predators) were placed into the tubs to give the smaller snails some incentive to climb. The fastest climbers won. Let’s watch part of one race:
If you’re a regular reader of the blog, you’ll realize that we often talk about similar research questions or ideas in the context of different projects. As David mentioned in his description of the Baymouth Bar project, this overlap is usually intentional: as ecologists, we’re interested not only in the specific habitats that we study, but also in the underlying factors that affect these habitats and the valuable services that they provide to we humans.
It may appear at times that we’ve been covering a diverse array of topics, and while this is true, all of these topics are interconnected- a web of topics centered around a couple of central themes. The diagram below is the map that shows where every post-topic fits into these central themes. Even the artists, writers, and photographers we occasionally feature have their place amongst ecological processes like sedimentation and the non-consumptive effects of predators. Every post from here on out will have one of these icons on it- if you don’t know what the icon means, just click on it and you’ll be back at this figure with an explanation:
Katie LotterhosFSU Department of Biological Sciences, FSU
When we look at a salt marsh, we see thousands of stems of cordgrass. But in reality, the coastline may be made up of only a few different genetic individuals. This is because Spartina can spread by growing clones of itself, with the exact same genetic code (a genotype). Why does it matter if we know whether or not a salt marsh is made up of one or many different genotypes? Well, different genotypes will have different abilities to resist pests or disease, or they may be tastier to eat for the little marsh critters like snails and grasshoppers. Since some genotypes will be better than others in different situations, we care about genetic diversity because it can be a buffer against an uncertain environment.
Last week, David and I (along with all the students and technicians in our labs, and over 500 other ecologists/students) attended the Benthic Ecology Meeting in Mobile, AL. You may well wonder – what goes on at a meeting of ecologists? And what does “benthic” mean anyway?