By Elaina Hancock / UConn Communications
The Deepwater Horizon disaster began on April 20, 2010 with an explosion on a BP-operated oil drilling rig in the Gulf of Mexico that killed 11 workers. Almost immediately, oil began spilling into the waters of the gulf, an environmental calamity that took months to bring under control, but not before it became the largest oil spill in the history of the petroleum industry.
Nearly 10 years have passed since then, and the oil slick has long since dispersed. Yet, despite early predictions, area wildlife are still feeling the effects of that oil, and research published in Environmental Toxicology and Chemistry has shown that negative health impacts have befallen not only dolphins alive at the time of the spill, but also in their young, born years later.
A team of researchers, including UConn Department of Pathobiology Professor and Director of the Connecticut Sea Grant College Program Sylvain De Guise, is part of a network conducting a long-term study on the health of bottlenose dolphins living in Louisiana’s Barataria Bay, in the vicinity of the disaster. This population of dolphins includes individuals who lived through the disaster and some born afterwards.
“We were on the ready and as soon as we could, and in 2011 we initiated a comprehensive health assessment where 60 to 80 people in the field worked together to find and safely pursue a multi-disciplinary, multi-expertise sample collection and study effort to assess the dolphins’ health,” says De Guise.
De Guise explains that after collection, samples were processed in 60 to 80 different specialized labs, and the researchers then regrouped to put the information together. De Guise’s research group specializes in studying the immune system, and from the very first set of samples they started to see consistent and abnormal immune responses in the Barataria Bay dolphins, compared with a similar control group of dolphins from Sarasota Bay who were not exposed to oil.
For the Barataria Bay dolphins, the researchers observed immune cells called T-cells that were overly responsive to stimulation. The body uses T-cells to respond to a stimulus, or something recognized as foreign. In particular, there were increased numbers of cells called regulatory T cells, or Tregs, which De Guise describes as the cells that help put the brakes on during an immune response to prevent the body from over-responding and doing more harm than good.
Despite the elevated numbers, De Guise says they were surprised to find the Barataria Bay dolphin Tregs appear to be functionally defective.
In some ways, the immune response can be looked at almost like a relay race, with cells signaling others to respond and join in the effort. In the case of T-helper (Th) cells, important signals called cytokines determine which type of T-helper will be next in the relay, and for the Barataria Bay dolphins, the signals are not relayed as expected.
“T-helper cells decide which direction your immune system will respond. If you have a pathogen that invades cells, a virus for example, you need a T-helper1 (Th1) response that will destroy the affected cells. If you have a pathogen that does not invade cells, like most types of bacteria, you need to generate antibodies to bind to those bacteria and help eliminate them with a Th2 response,” says De Guise.
In the lab, the researchers studied the immune cells from both dolphin populations by exposing them to proteins called cytokines which elicit predictable responses from the T-cells. The researchers also exposed T-cells from the control group dolphins to oil to see what would happen. In all samples of T-cells exposed to oil, Th2 responses were exaggerated compared to the control group.
“We were able to demonstrate that there was a difference in responsiveness between the populations, in both real-life and in-vitro tests which resulted in an increase in Th2 response in the Barataria Bay dolphins,” says De Guise.
The researchers went one step further by conducting a mouse study to see if a similar immune response could be seen in mice exposed to oil, and they did.
“The effects on the mouse immune system that we found were strikingly similar to what we saw in the dolphins,” says De Guise. “We want to show the likelihood of a cause and effect relationship and add to the weight of evidence that oil impacts the immune system in a way that is very reproducible across species. The changes that we found in the Barataria Bay dolphins is specific to oil and not related to something else.”
Though the researchers are not sure if the abnormal immune response is due to the initial exposure or continued exposure to oil still present in sediments, De Guise says the result may lead to the dolphins being more susceptible to pathogens like viruses, due to dysfunctional T-reg cells. Only future studies can shed light, and De Guise says now that images of oil slicks are no longer capturing attention, funding is harder to come by.
However, for this study, De Guise notes it is very rare to have such a long-term, detailed follow-up on a wild population of animals, and the researchers were very surprised to see effects in a second generation who did not live through the disaster.
“The outcome of this work is that we are not sure if these effects are reversible or not. The longer we look, they are still around. I think it is the first time we find such evidence across generations in a wild animal population, and that is scary. It raises concern for the long-term recovery of these dolphins,” says De Guise. “These are long-lived mammals and, in many ways, not unlike humans who live in the area and depend on natural resources. It is interesting science, but it is very scary.”
This article was first published in UConn Today: https://today.uconn.edu/2021/03/deepwater-horizons-long-lasting-legacy-for-dolphins/.