South Teams Research and Reimagine Marsh Grass on Dauphin Island
Posted on August 22, 2025
Along the shore of Aloe Bay on Dauphin Island, the tide lapped against a new green fringe of native salt marsh grass. 窪蹋勛圖厙 an hour after sunrise on a Wednesday in late July, two teams from South gathered, coming from different scientific directions with a common aim protecting and boosting the viability of that marsh grass for generations to come.
The scene unfolded on a sandy stretch of land the 窪蹋勛圖厙 Foundation donated to South in 2023, just down the shore from the future site of the schools outdoor classroom on the bay.
From the Stokes School of Marine and Environmental Sciences, Associate Professor Ron Bakers group focused on strategic planting and long-term monitoring to track how the shoreline changes over time.
Biology Associate Professor Jeremiah Henning and masters student Camille Thompson came one step closer in their quest to find out whether a specific marsh grass planted with beneficial root fungi will grow stronger and more resilient.
Both efforts rely on Spartina alterniflora, a hardy salt marsh plant that stabilizes shorelines and creates vital habitat for fish, shellfish and birds.
For Bakers group, Spartina is a living signal of how well the shoreline is holding, now and in the future. During the summer, Baker coordinated a project that brought around 100 volunteers and students who planted 16,000 salt marsh plugs of Spartina along the shore in just two days.
For the biologists on the shore, this work is proof of concept to generate preliminary data for a three-year, $1.1 million National Science Foundation-funded study; Henning will serve as one of three principal investigators. Henning and Thompson see Spartina as the center of a game-changing ecological experiment.
At the shoreline, teams from both groups planted 2,000 Spartina plugs that Thompson had inoculated with a mix of native fungi she gathered from other isolated marshes around the island.
The idea is that these fungal partners may help the plants tolerate high salinity and transplant stress, Thompson said.
For the study, Bakers group laid out experimental plots with different planting densities, allowing researchers and future students to monitor which layouts work best under wave and boat-wake pressure.
Henning and Thompson will be scaling up next summer, taking the knowledge gained at Aloe Bay all the way to the Texas coast, where bays are becoming saltier due to rising sea levels that push the water inland, in addition to a reduction of rainfall in South Texas.
Aloe Bay gives us a chance to test our approach and gather real data before expanding, said Thompson, whose master's thesis sets the stage for that larger effort. After completing her masters, she plans to continue to work on the project as a Ph.D. student under Hennings guidance.
This is a great opportunity to gather real-world data and see how local fungi affect plant survival, she said. Its exciting to know that what were learning here could help shape restoration efforts in other parts of the Gulf.
Audio of Camille Thompson
My name is Camille Thompson. I'm a second-year graduate student, and currently I'm studying mycorrhizal fungi and the mutualistic benefits with salt marsh vegetation. Here at South with the ocean only being 45 minutes away, it's really easy to take trips back and forth for monitoring reasons. So it's been very helpful that the University is so close to these coastal ecosystems. I've always been interested in marine biology. I think I my interest got piqued at about 10 years old, and as I have been seeing these things kind of develop with climate change, the question has always been in my head, "Okay, how are we going to stop it, fix it, change it?" That is the thing that drives me is just trying to preserve and restore as much as we can. I love having free weekends to go to the beach. People say that if you live near the beach, then it's not as exciting to you getting to go. That has not been proven to me so far. Definitely a happy place.
Alex Rodriguez, Bakers lab manager, has a role that takes place both on land and in the air, using multi-spectral drone imagery to assess plant health from above a technique that will add another layer of analysis and student learning opportunity.
The cameras of multi-spectral drones include pictures of whats not visible to the naked eye, said Rodriguez, who is based at the Dauphin Island Sea Lab. From this imagery, we can measure the greenness of the plants, telling us what plants are healthy and thriving. So, we can monitor how this restoration progresses, and being just five minutes from our office allows us to do that regularly.
This collaboration to restore and sustain a vulnerable shore with a robust spread of Spartina could have a lengthy legacy. This gives us an opportunity to not just teach students how to survey vegetation, Baker said. They can actually do it in a way where they can ask the question, Which of these experimental treatments works best? Students will be able to study it and track its progress for years to come.
