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Dryad

Data from: Rising temperatures, molting phenology and epizootic shell disease in the American lobster

Cite this dataset

Groner, Maya L. et al. (2018). Data from: Rising temperatures, molting phenology and epizootic shell disease in the American lobster [Dataset]. Dryad. https://doi.org/10.5061/dryad.n102b1s

Abstract

Phenological mismatch, maladaptive changes in phenology resulting from altered timing of environmental cues, is an increasing concern in many ecological systems, yet its effects on disease are poorly characterized. American lobster (Homarus americanus) is declining at its southern geographic limit. Rising seawater temperatures are associated with seasonal outbreaks of epizootic shell disease (ESD), which peaks in prevalence in the fall. We used a 34-year mark-recapture dataset to investigate relationships between temperature, molting phenology, and ESD in Long Island Sound, where temperatures are increasing at 0.4 °C per decade. Our analyses support the hypothesis that phenological mismatch is linked to the epidemiology of ESD. Warming spring temperatures are correlated with earlier spring molting. Lobsters lose diseased cuticle by molting, and early molting increases the intermolt period in the summer, when disease prevalence is increasing to a fall peak. In juvenile and adult male lobsters, September ESD prevalence was correlated with early molting, while October ESD prevalence was correlated with summer seawater temperature. This suggests that temperature-induced molting phenology affects the timing of the onset of ESD, but, later in the summer, this signal is swamped by the stronger signal of summer temperatures, which we hypothesize are associated with an increased rate of new infections. October ESD prevalence was ~80% in years with hot summers, and ~30% in years with cooler summers. Yearly survival of diseased lobsters is <50% that of healthy lobsters. Thus, population impacts of ESD are expected to increase with increasing seawater temperatures.

Usage notes

Location

USA
Connecticut
Long Island Sound