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First Report of an Emerging Ulcerative Skin Disease in Invasive Lionfish

Holden E. Harris, Alexander Q. Fogg, Roy P. Yanong, Salvatore Frasca Jr., Theresa Cody, Thomas B. Waltzek, and William F. Patterson III

Introduction

The invasion of the Indo-Pacific lionfish (Pterois volitans/miles complex) into the western Atlantic Ocean is considered the most successful marine fish invasion (Morris and Whitfield 2009). Lionfish were first detected offshore of southeast Florida in 1985 and are now established throughout the western Atlantic Ocean, the Caribbean Sea, and the Gulf of Mexico (GOM) (Schofield 2010, Schofield 2018). Lionfish consume native species and compete with them for habitat and food (Morris and Akins 2009), and negatively impact native reef fish communities (Green et al. 2012; Albins 2015; Dahl et al. 2016). Lionfish occupy many marine habitats in the invaded range, including artificial and natural reefs (Morris and Whitfield 2009; Dahl and Patterson 2014), patch reefs in estuaries (Jud and Layman 2012), seagrass beds (Claydon et al. 2012), and mangroves (Barbour et al. 2010). Lionfish have broad tolerances to temperature (Kimball et al. 2004) and salinity (Jud et al. 2015), and they are found as deep as 400 m or 1,300 ft (Schofield 2010). Given the abundance and distribution of invasive lionfish, natural mechanisms may be necessary to achieve region-wide population control.

Densities of lionfish in their native Indo-Pacific range are substantially lower than densities reported in their invaded western Atlantic range (Kulbicki et al. 2012). However, the primary mechanism that controls their native range densities (e.g., predators, parasites, disease, or competition for resources) is unknown. Reports indicate that native predators may be learning to consume lionfish in parts of their invaded range (Maljkovic et al. 2008; Diller et al. 2014; Muñoz 2017), but there is no evidence that invasive lionfish populations are controlled by either predators (Hackerott et al. 2013; Valdivia et al. 2014) or parasites (Sikkel et al. 2014; Sellers et al. 2015; Fogg et al. 2016; Tuttle et al. 2017). Thus, natural biocontrol of lionfish to this point is likely limited to competition for resources (Chagaris et al. 2017) and cannibalism (Dahl et al. 2017).

High lionfish population densities (Dahl and Patterson 2014) and low genetic diversity (Pérez-Portela et al. 2018) in the invaded range could make their populations more susceptible to disease. Lionfish support different communities of environmentally derived microbes than native Caribbean reef fishes (Stevens and Olson 2013), and these microbial communities are differentially colonized by microbes from their local environments (Stevens and Olson 2015). The lack of an adequate immune response to pathogens (i.e., disease-causing microbes) present in the invaded systems may cause invasive lionfish populations to be susceptible to disease (Lee and Klasing 2004; White and Perkins 2012).

Here, we report the first observed incidences of an emerging ulcerative skin disease in lionfish in the Western Atlantic Ocean, the GOM and the Caribbean Sea. This disease has recently appeared in the population, and its geographic range appears to be expanding. The purpose of this extension publication is to (1) describe the gross pathology (i.e., tissue appearance and condition) of the disease, (2) present initial reports of the chronology and geography for reported observations of this ulcerative skin disease, (3) outline our current knowledge gaps and research efforts, and, (4) encourage divers, lionfish harvesters, conservation organizations, and scientists working with lionfish to report and submit photograph observations of lionfish with skin ulcers to the Fish Kill Hotline at the Florida Fish and Wildlife Conservation Commission (FWC), 1-800-636-0511.

Gross Pathology of Ulcerations

Lionfish with skin ulcers were collected in the northern Gulf of Mexico (nGOM) and processed for diagnostic evaluation by researchers at the University of Florida (UF) and FWC. Representative fish were subjected to necropsy (i.e., postmortem dissection of carcasses). Necropsy results provided evidence that skin ulcers were variable in size, location, and number among ulcerated lionfish. Deep skin ulcers often exposed skeletal muscle, with a sloughing of dead tissue (Figure 1). Skin tissue near the ulcers showed evidence of healing, suggesting that the initial wound occurred potentially days or weeks before those lionfish were collected.

Histopathology (i.e., microscopic examination of tissue) and bacteriology (i.e., examination of the bacterial community) were performed on lionfish to identify the causative agent (i.e., disease-causing organism). These evaluations were performed on multiple tissues, including the leading edges of skin ulcers, as well as kidney and brain tissue. Microscopic wet mount evaluations (i.e., examination of fresh tissue squashes) of the fins, gills, and skin ulcers were negative for parasites, water molds, or other potential infectious causes. Ultimately, a causative agent was not identified during these initial evaluations.

 

Figure 1. Images of invasive lionfish Pterois volitans/miles with the ulcerative skin disease. Skin ulcers varied in size, location, and number on each fish. White arrows indicate position of skin ulcer. A) Photo taken in the field of a lionfish sampled near Destin, FL, on October 29, 2017 (photo credit: H. Harris). B) Lionfish during diagnostic evaluations at the FWC Fish and Wildlife Health laboratory (photo credit: FWC). C) Lionfish sampled near Destin, FL, on March 15, 2018 with a skin ulcer that appears to be covered by scar tissue (photo credit: A. Fogg). D) Lionfish observed underwater with a remotely operated vehicle off Destin, FL, on October 16, 2017 (photo credit: J. Tarnecki). E) Two lionfish sampled during the lionfish tournament on Grand Cayman Island, September 23, 2017. (photo credit: J. Washington). F) Lionfish from Bonaire on March 4, 2018 (photo credit: J. Spruit).
Figure 1.  Images of invasive lionfish Pterois volitans/miles with the ulcerative skin disease. Skin ulcers varied in size, location, and number on each fish. White arrows indicate position of skin ulcer. A) Photo taken in the field of a lionfish sampled near Destin, FL, on October 29, 2017 (photo credit: H. Harris). B) Lionfish during diagnostic evaluations at the FWC Fish and Wildlife Health laboratory (photo credit: FWC). C) Lionfish sampled near Destin, FL, on March 15, 2018 with a skin ulcer that appears to be covered by scar tissue (photo credit: A. Fogg). D) Lionfish observed underwater with a remotely operated vehicle off Destin, FL, on October 16, 2017 (photo credit: J. Tarnecki). E) Two lionfish sampled during the lionfish tournament on Grand Cayman Island, September 23, 2017. (photo credit: J. Washington). F) Lionfish from Bonaire on March 4, 2018 (photo credit: J. Spruit).

 

Observations of Ulcerated Lionfish

The first documented report of lionfish presenting with skin ulcers occurred on August 5, 2017, from lionfish harvested off artificial reefs near Destin, FL (Table 1). On this day, 201 (40%) of 503 harvested lionfish had skin ulcers. Additionally, a single dead lionfish was observed on the seabed adjacent to an artificial reef, and multiple dead lionfish were observed floating at the sea surface (personal communication, J. Livingston, Dreadknot Charters).

Lionfish with the ulcerative skin disease have since been reported from waters of the West Florida Shelf, the East Florida Shelf, and the Florida Keys, as well as throughout the Caribbean Sea (Table 1; Figure 2). To date, reports from the nGOM have also had the highest reported numbers and percentages of ulcerated lionfish. In the wider Caribbean region, ulcerated lionfish have been reported from The Bahamas, Grand Cayman, Aruba, St. Croix, Bonaire, Útila, and Belize (Table 1; Figure 2). Images of lionfish published via various internet media and included in personal communication with the authors suggest ulcerated lionfish in the Caribbean Sea and East Florida Shelf regions (Figure 1, E and F) have a gross pathology similar to that found in ulcerated lionfish observed in the nGOM (Figure 1, A–D). However, it is unknown whether the causative agent is shared among regions where ulcerated lionfish have been observed.

Preliminary data collected from lionfish harvested in the nGOM indicate a general decline in the proportion of lionfish presenting with skin ulcers through winter and early spring 2018. Additionally, many of the ulcerated lionfish harvested during spring and early summer of 2018 had scar tissue suggestive of healing associated with wounds (Figure 1, C).

 

Figure 2. Locations in the Gulf of Mexico, Caribbean Sea, and Atlantic Ocean where observations of invasive lionfish Pterois volitans/miles with skin ulcers have been reported.
Figure 2.  Locations in the Gulf of Mexico, Caribbean Sea, and Atlantic Ocean where observations of invasive lionfish Pterois volitans/miles with skin ulcers have been reported.

 

Knowledge Gaps and Upcoming Research

Further research to determine a causative agent will help clarify how the ulcers affect lionfish flesh, impacts on lionfish health, and the potential for the disease to transmit to other species. To our knowledge, there have been no reported cases of human illness due to consuming ulcerated lionfish. However, if a lionfish has ulcers or appears unhealthy, we suggest you avoid direct contact and not eat the ulcerated lionfish. If you have touched an ulcerated fish, wash with soap and water. Fresh lionfish is a tasty, healthful source of protein when handled and prepared properly. Eating invasive lionfish is encouraged as one of the best options to mitigate their impacts on native reef communities.

Collaborative research between UF and FWC scientists is underway to describe the cause of this ulcerative disease. This research uses molecular tools to evaluate lionfish sampled across a wide geographic range and determine whether the disease originates from a virus. Using a multidisciplinary approach, tissue samples from ulcerated lionfish and seemingly healthy lionfish will be processed using polymerase chain reaction (PCR) assays that target known fish viruses. Viral and bacterial genetic material sourced directly from the environment will be processed using next-generation sequencing techniques. Determining the causative agent will provide insight into the lethal and sublethal effects of the disease on lionfish and the likelihood that the disease will transmit to other species.

Concurrently, research is being conducted to evaluate the effects of the ulcerative disease on individual lionfish and on lionfish populations. We are continuing long-term monitoring efforts at nGOM artificial and natural reef sites via remote operated vehicle video (ROV) surveys. Data from ROV surveys of lionfish densities conducted before disease emergence will be compared to data on lionfish densities collected after disease emergence. We are also examining the relative condition (i.e., whether fish are heavier or lighter than predicted for a given length), to compare the relative condition of lionfish with skin ulcers to the relative condition of apparently healthy individuals. Finally, commercial lionfish catches and tournament landings are being analyzed for potential changes in population size and age structure. Together, this information will be used to assess potential changes in lionfish abundances and evaluate implications for the lionfish fishery and reef fish communities.

Where to Report Observations of Ulcerated Lionfish

If you observe lionfish with skin ulcers, please report your observations to the FWC Fish Kill Hotline by telephone (1-800-636-0511), online (https://app.myfwc.com/FWRI/FishKillReport/Submit.aspx), or by using the FWC Reporter mobile application from iTunes or Google Play. If possible, please include the following: 1) the date of the occurrence, 2) the location, 3) the bottom water temperature, and 4) photographs of the lionfish. The Fish Kill Hotline is maintained by the FWC group based in St. Petersburg at the FWC Research Institute, the research arm of the FWC. Every report is documented in the searchable database and available online at https://app.myfwc.com/FWRI/FishKillReport/SearchResults.aspx.

Conclusion

The first recorded observation of an ulcerative skin disease in lionfish occurred on August 5, 2017, in northwest Florida. Subsequent observations have been reported offshore of states bordering the GOM, along the US east coast, and in locations throughout the Caribbean. The highest numbers of ulcerated lionfish have been reported in northwest Florida. Pathologic examinations found skin ulcers that varied in size and location, often with skin tissue decay that exposed deeper muscle tissues. While a pathogen was not identified during initial diagnostic evaluations, we anticipate molecular tools will enable us to better understand the origin of this ulcerative disease and the potential for this disease to be transmitted to other species. At the same time, we are evaluating the lethal and sublethal effects of this ulcerative skin disease and how the disease may ultimately impact lionfish populations, the lionfish fishery, and reef fish communities. We ask for your help: please report any observations of ulcerated lionfish to the FWC Fish Kill Hotline (1-800-636-0511).

Acknowledgments

We thank Jeff Hill for his initial advice and review and the many individuals and organizations who provided information regarding the chronology and geography of observed ulcerations: (alphabetical order) Alfonso Aguilar-Perera, Brian Asher, Micah Bakenhaster, Buck Beasley, Rachel Bowman, Brian Bounds, Bibi Burnette, Paul Cordone, Caren Eckrich, Corey Eddy, Allie ElHage, Meaghan Faletti, Tom Frazer, Michael Funk, Steve Garner, Scott Harrell, Andre Johnson, Bradley Johnson, Michelle Johnston, Lisette Keus, Joe Livingston, Josh Livingston, Paul Maneval, Carl Molitor, Eliezer Muñoz, Sean Patterson, Michael Pement, Tommy Phelps, Alan Pierce, Adam Richardson, Serena Rivero, Andy Ross, Ben Schapiro, Grayson Shepard, Tim Shivers, Jerome Spruit, Kali Spurgin, Ron Surrency, Joe Tarnecki, Hanna Tillotson, Bas Tol, Cory Trier, Justin Wallheiser, Jason Washington, Adam Wise, Virgil Zetterlind, Bonaire Lionfish Hunters, Caribbean Oceanic Restoration and Education Foundation, Cayman United Lionfish League, Coast Watch Alliance, Deepwater Mafia Dive Club, and Lionfish Caribbean. Financial support for this research is provided by the Florida Restore Act Centers of Excellence Program, Gulf of Mexico Research Initiative, and Florida Fish and Wildlife Conservation Commission. Financial support for H.E. Harris is provided by the National Science Foundation Graduate Research Fellowship Program [grant no. DGE-1315138]. Additional support provided by Florida Sea Grant. Opinions, findings, conclusions, or recommendations expressed in this document do not necessarily reflect the views of our supporting organizations.

References

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Tables

Table 1. 

Initial reports of an ulcerative skin disease in lionfish (Pterois volitans/miles), including date of first report, location, and reporting diver/contact. NR = not recorded.

Date of First Report

Location

Diver/Contact

August 5, 2017

Destin, FL

Alex Fogg

August 13, 2017

St Petersburg, FL

Alex Fogg

August 18, 2017

Apalachicola, FL

Grayson Shepard

Late August, 2017

Grand Cayman

Jason Washington

September 5, 2017

St. Croix

Michael Funk

October 18, 2017

Mississippi

Deepwater Mafia Dive Club

October 26, 2017

Pensacola, FL

Alex Fogg

October 29, 2017

West Louisiana

Hell Divers Spearfishing Club

October 29, 2017

Alabama

Deepwater Mafia Dive Club

November 1, 2017

South Carolina/Georgia

Ron Surrency

December 16, 2017

Marathon, FL

Rachel Bowman

Late 2017

Bahamas

Tom Frazer

January 24, 2018

Bonaire

Jerome Spruit

March 31, 2018

Key Largo, FL

Alex Fogg

April 28, 2018

Islamorada, FL

Paul Cardone

May 10, 2018

Aruba

Raven Walker

May 24, 2018

Mexico Beach, FL

Hanna Tillotson

June 10, 2018

Ft. Pierce, FL

Alex Fogg

NR

Belize

Eliezer Muñoz

NR

Útila, Honduras

Bibi Burnette

 
Peer Reviewed

Publication #FA209

Release Date:October 18, 2018

Reviewed At:January 18, 2022

Related Experts

Yanong, Roy P.

Specialist/SSA/RSA

University of Florida

Fact Sheet

About this Publication

This document is FA209, one of a series of the School of Forest, Fisheries, and Geomatics Sciences, Program in Fisheries and Aquatic Sciences, UF/IFAS Extension. Original publication date September 2018. Visit the EDIS website at https://edis.ifas.ufl.edu for the currently supported version of this publication.

About the Authors

Holden E. Harris, graduate research fellow, PhD student, School of Natural Resources and Environment and School of Forest, Fisheries, and Geomatics Sciences, Program in Fisheries and Aquatic Sciences; Alexander Q. Fogg, Marine Resource Coordinator, Okaloosa County Board of County Commissioners, Fort Walton Beach, FL; Roy P. Yanong, Extension veterinarian, Tropical Aquaculture Laboratory and professor, School of Forest, Fisheries, and Geomatics Sciences, Program in Fisheries and Aquatic Sciences; Salvatore Frasca Jr., professor, Department of Comparative, Diagnostic, and Population Medicine, College of Veterinary Medicine; UF/IFAS Extension; Theresa Cody, associate research scientist, Fish and Wildlife Research Institute, Florida Fish and Wildlife Conservation Commission, St. Petersburg, FL; Thomas B. Waltzek, associate professor, Department of Infectious Diseases and Immunology, College of Veterinary Medicine; and William F. Patterson III; associate professor, School of Forest, Fisheries, and Geomatics Sciences, Program in Fisheries and Aquatic Sciences; UF/IFAS Extension, Gainesville, FL, 32611.

Contacts

  • Roy Yanong