Click
here to close Hello! We notice that
you are using Internet Explorer, which is not supported by Echinobase
and may cause the site to display incorrectly. We suggest using a
current version of Chrome,
FireFox,
or Safari.
PLoS One
2018 Jan 01;133:e0192870. doi: 10.1371/journal.pone.0192870.
Show Gene links
Show Anatomy links
Large-scale impacts of sea star wasting disease (SSWD) on intertidal sea stars and implications for recovery.
Miner CM
,
Burnaford JL
,
Ambrose RF
,
Antrim L
,
Bohlmann H
,
Blanchette CA
,
Engle JM
,
Fradkin SC
,
Gaddam R
,
Harley CDG
,
Miner BG
,
Murray SN
,
Smith JR
,
Whitaker SG
,
Raimondi PT
.
???displayArticle.abstract???
Disease outbreaks can have substantial impacts on wild populations, but the often patchy or anecdotal evidence of these impacts impedes our ability to understand outbreak dynamics. Recently however, a severe disease outbreak occurred in a group of very well-studied organisms-sea stars along the west coast of North America. We analyzed nearly two decades of data from a coordinated monitoring effort at 88 sites ranging from southern British Columbia to San Diego, California along with 2 sites near Sitka, Alaska to better understand the effects of sea star wasting disease (SSWD) on the keystone intertidal predator, Pisaster ochraceus. Quantitative surveys revealed unprecedented declines of P. ochraceus in 2014 and 2015 across nearly the entire geographic range of the species. The intensity of the impact of SSWD was not uniform across the affected area, with proportionally greater population declines in the southern regions relative to the north. The degree of population decline was unrelated to pre-outbreak P. ochraceus density, although these factors have been linked in other well-documented disease events. While elevated seawater temperatures were not broadly linked to the initial emergence of SSWD, anomalously high seawater temperatures in 2014 and 2015 might have exacerbated the disease''s impact. Both before and after the onset of the SSWD outbreak, we documented higher recruitment of P. ochraceus in the north than in the south, and while some juveniles are surviving (as evidenced by transition of recruitment pulses to larger size classes), post-SSWD survivorship is lower than during pre-SSWD periods. In hindsight, our data suggest that the SSWD event defied prediction based on two factors found to be important in other marine disease events, sea water temperature and population density, and illustrate the importance of surveillance of natural populations as one element of an integrated approach to marine disease ecology. Low levels of SSWD-symptomatic sea stars are still present throughout the impacted range, thus the outlook for population recovery is uncertain.
???displayArticle.pubmedLink???
29558484
???displayArticle.pmcLink???PMC5860697 ???displayArticle.link???PLoS One
Fig 2. Heat map showing annual changes in abundance of P. ochraceus for each site relative to the long-term mean.The annual relative population size was calculated by dividing the total number of adult P. ochraceus (>30 mm radius) counted within long-term permanent plots for a given year (or mean count in years with >1 survey year-1) by the long-term annual mean number of stars counted at a given site through 2013. 2013 is indicated by a vertical line, and separates pre-SSWD years from post-SSWD years. Unshaded cells represent years when surveys were not done.
Fig 3. Deviations of daily sea water temperature from long-term means (lines) overlaid on annual (WA, OR, CA North) or semiannual (CA Central, CA South) P. ochraceus abundance (bars) relative to long-term mean.Temperature deviations were displayed using a weekly smoother to emphasize longer-term patterns (rather than daily fluctuations). Sea star abundance ratios are averaged across all sites within each region for a given season (SP = spring [Feb-Apr], SU = summer [May-Aug], FA = fall [Sep-Nov]). Horizontal lines where ratio = 1 were included to illustrate deviations from long-term mean.
Fig 4. Total number of juvenile P. ochraceus (“radius” ≤ 30 mm) counted within long-term permanent plots at each site over time.For sites that were sampled > 1 time year-1, the mean total number for that year is displayed. 2013 is indicated by a vertical line, and separates pre-SSWD years from post-SSWD years. Unshaded cells represent years when surveys were not done.
Altizer,
Climate change and infectious diseases: from evidence to a predictive framework.
2013, Pubmed
Altizer,
Climate change and infectious diseases: from evidence to a predictive framework.
2013,
Pubmed
Anderson,
The invasion, persistence and spread of infectious diseases within animal and plant communities.
1986,
Pubmed
Bates,
Effects of temperature, season and locality on wasting disease in the keystone predatory sea star Pisaster ochraceus.
2009,
Pubmed
,
Echinobase
Burge,
Climate change influences on marine infectious diseases: implications for management and society.
2014,
Pubmed
Burge,
Complementary approaches to diagnosing marine diseases: a union of the modern and the classic.
2016,
Pubmed
Burge,
Special issue Oceans and Humans Health: the ecology of marine opportunists.
2013,
Pubmed
,
Echinobase
Denny,
Celestial Mechanics, Sea-Level Changes, and Intertidal Ecology.
1998,
Pubmed
Dungan,
Catastrophic decline of a top carnivore in the gulf of california rocky intertidal zone.
1982,
Pubmed
,
Echinobase
Eisenlord,
Ochre star mortality during the 2014 wasting disease epizootic: role of population size structure and temperature.
2016,
Pubmed
,
Echinobase
Fey,
Recent shifts in the occurrence, cause, and magnitude of animal mass mortality events.
2015,
Pubmed
Groner,
Managing marine disease emergencies in an era of rapid change.
2016,
Pubmed
Harley,
Color polymorphism and genetic structure in the sea star Pisaster ochraceus.
2006,
Pubmed
,
Echinobase
Hewson,
Densovirus associated with sea-star wasting disease and mass mortality.
2014,
Pubmed
,
Echinobase
Kohl,
Decreased Temperature Facilitates Short-Term Sea Star Wasting Disease Survival in the Keystone Intertidal Sea Star Pisaster ochraceus.
2016,
Pubmed
,
Echinobase
Lafferty,
Marine disease impacts, diagnosis, forecasting, management and policy.
2016,
Pubmed
Lafferty,
Infectious diseases affect marine fisheries and aquaculture economics.
2015,
Pubmed
Lessios,
The Great Diadema antillarum Die-Off: 30 Years Later.
2016,
Pubmed
,
Echinobase
Maynard,
Improving marine disease surveillance through sea temperature monitoring, outlooks and projections.
2016,
Pubmed
,
Echinobase
McCallum,
How should pathogen transmission be modelled?
2001,
Pubmed
Menge,
Sea Star Wasting Disease in the Keystone Predator Pisaster ochraceus in Oregon: Insights into Differential Population Impacts, Recovery, Predation Rate, and Temperature Effects from Long-Term Research.
2016,
Pubmed
,
Echinobase
Montecino-Latorre,
Devastating Transboundary Impacts of Sea Star Wasting Disease on Subtidal Asteroids.
2016,
Pubmed
,
Echinobase
Pincebourde,
An intertidal sea star adjusts thermal inertia to avoid extreme body temperatures.
2009,
Pubmed
,
Echinobase
Schultz,
Evidence for a trophic cascade on rocky reefs following sea star mass mortality in British Columbia.
2016,
Pubmed
,
Echinobase
Sunday,
Ocean circulation model predicts high genetic structure observed in a long-lived pelagic developer.
2014,
Pubmed
,
Echinobase
Wares,
What doesn't kill them makes them stronger: an association between elongation factor 1-α overdominance in the sea star Pisaster ochraceus and "sea star wasting disease".
2016,
Pubmed
,
Echinobase
