Kathryn P Sutherland, Ashton Griffin, Andrew Park, James W Porter, Scott F Heron, C Mark Eakin, Brett Berry, Dustin W Kemp, Keri M Kemp, Erin K Lipp, John P Wares
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引用次数: 0
Abstract
Declining coral populations worldwide place a special premium on identifying risks and drivers that precipitate these declines. Understanding the relationship between disease outbreaks and their drivers can help to anticipate when the risk of a disease pandemic is high. Populations of the iconic branching Caribbean elkhorn coral Acropora palmata have collapsed in recent decades, in part due to white pox disease (WPX). To assess the role that biotic and abiotic factors play in modulating coral disease, we present a predictive model for WPX in A. palmata using 20 yr of disease surveys from the Florida Keys plus environmental information collected simultaneously in situ and via satellite. We found that colony size was the most influential predictor for WPX occurrence, with larger colonies being at higher risk. Water quality parameters of dissolved oxygen saturation, total organic carbon, dissolved inorganic nitrogen, and salinity were implicated in WPX likelihood. Both low and high wind speeds were identified as important environmental drivers of WPX. While high temperature has been identified as an important cause of coral mortality in both bleaching and disease scenarios, our model indicates that the relative influence of HotSpot (positive summertime temperature anomaly) was low and actually inversely related to WPX risk. The predictive model developed here can contribute to enabling targeted strategic management actions and disease surveillance, enabling managers to treat the disease or mitigate disease drivers, thereby suppressing the disease and supporting the persistence of corals in an era of myriad threats.
期刊介绍:
DAO publishes Research Articles, Reviews, and Notes, as well as Comments/Reply Comments (for details see DAO 48:161), Theme Sections and Opinion Pieces. For details consult the Guidelines for Authors. Papers may cover all forms of life - animals, plants and microorganisms - in marine, limnetic and brackish habitats. DAO''s scope includes any research focusing on diseases in aquatic organisms, specifically:
-Diseases caused by coexisting organisms, e.g. viruses, bacteria, fungi, protistans, metazoans; characterization of pathogens
-Diseases caused by abiotic factors (critical intensities of environmental properties, including pollution)-
Diseases due to internal circumstances (innate, idiopathic, genetic)-
Diseases due to proliferative disorders (neoplasms)-
Disease diagnosis, treatment and prevention-
Molecular aspects of diseases-
Nutritional disorders-
Stress and physical injuries-
Epidemiology/epizootiology-
Parasitology-
Toxicology-
Diseases of aquatic organisms affecting human health and well-being (with the focus on the aquatic organism)-
Diseases as indicators of humanity''s detrimental impact on nature-
Genomics, proteomics and metabolomics of disease-
Immunology and disease prevention-
Animal welfare-
Zoonosis