Prevalence and characterization of Salmonella shed by captive and free-range California sea lions (Zalophus californianus) from a rehabilitation center and three state reserves along the California coast.

Salmonella is a genus of zoonotic bacteria that can infect a variety of animals, and may cause gastrointestinal disease in marine mammals. Many of the same Salmonella serotypes are shed by California sea lions (Zalophus californianus) and humans, which poses transmission questions and public health concerns. In this study, 454 fecal samples from three free-ranging California sea lion populations along the California coast and from animals undergoing rehabilitation at The Marine Mammal Center, Sausalito, California, were screened for the presence of Salmonella. In addition to fecal samples, 39 presumed vomitus samples were collected and processed. Of the 454 samples processed, 312 were from free-ranging sites and 142 were from rehabilitating California sea lions. A total of nine fecal samples were positive for Salmonella, yielding a 2.0% overall prevalence, as well as two presumed vomitus samples (5.1% prevalence). Salmonella shedding prevalence was 1.6% in samples collected from free-ranging animals, and 2.8% in rehabilitating animals. Four serotypes were found among the 11 positive samples, with Salmonella Enteritidis the most prevalent (64%). Antimicrobial resistance testing and pulsed-field gel electrophoresis were performed to further characterize isolates. Experiments were carried out to determine the minimal number of Salmonella required for detection by the methods used. It was determined that at least 10' colony-forming units per gram of feces was required for detection. The prevalence of Salmonella Enteritidis, and diversity of serotypes discovered is considerably different from those reported in previous studies. Overall, this study provides new insights into the epidemiology of Salmonella in California sea lions present in multi-use coastal ecosystems.

Fecal indicator bacteria and zoonotic pathogens in marine snow and California mussels (Mytilus californianus).

Pollution of nearshore waters with disease-causing microorganisms impacts ecosystems health through illness and deaths in people and wildlife, as well as negative socioeconomic consequences of impaired marine resources. Insight on pathogen ecology in coastal habitats is crucial for accurately mitigating inputs and impacts of microbial pollution. Three objectives were addressed to (i) compare fecal pollution in proximity to (a) freshwater runoff, and (b) endemic marine wildlife; (ii) evaluate presence and magnitude of fecal microorganisms in marine snow and mussels and (iii) determine if pathogens in mussels and FIB levels in seawater or mussels are correlated. Sampling during the wet season, proximity to freshwater, and FIB levels in mussel homogenates (but not seawater) were associated with pathogen presence in mussels. Pathogens and FIB were enriched in aggregate-rich fractions, further supporting an important role of marine snow in pathogen transmission. The lack of association between FIB in surrounding waters and presence of pathogens in mussels calls into question current regulations for insuring safe seafood to consumers in the United States, and alternative monitoring approaches such as direct testing for select pathogens should be further evaluated.

Effects of transparent exopolymer particles and suspended particles on the survival of Salmonella enterica serovar Typhimurium in seawater.

The bacterium Salmonella enterica can infect marine mammals and has been increasingly implicated in seafood-borne disease outbreaks in humans. Despite the risk this zoonotic agent poses to animals and people, little is known regarding the environmental factors that affect its persistence in the sea. The goal of this study was to evaluate the impact of two constituents on the survival of Salmonella in the marine environment: transparent exopolymer particles (TEP) and suspended particles. A decay experiment was conducted by spiking Salmonella into bottles containing seawater, seawater with alginic acid as a source of TEP, filtered seawater or filtered seawater with alginic acid. Survival of Salmonella was monitored using culture followed by enrichment assays to evaluate if the bacteria entered a viable but non-cultivable (VBNC) state. Salmonella cell counts dropped significantly faster (P ≤ 0.05) in the unfiltered seawater samples with and without TEP. The slowest decay occurred in filtered seawater containing alginic acid, with VBNC Salmonella persisting for 17 months. These findings suggest that TEP may favor Salmonella survival while suspended particles facilitate its decay. Insight on the survival of allochthonous, zoonotic pathogens in seawater can guide monitoring, management and policy decisions relevant to wildlife and human public health.