Multisystemic Inflammatory Disease in Pheasantshell (Unionidae, Actinonaias Pectorosa) Associated with Yokenella Regensburgei Infection at Sites Experiencing Seasonal Mass Mortality Events

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2024 Aug 27

PMID 39190757

Authors

Jeronimo G Da Silva Neto

Rebecca H Hardman

Augustin C Engman

Gerald R Dinkins

Timothy W Lane

Michael M Fry

Christian R Rines

Amber L Bisenieks

Sree Rajeev

Michelle M Dennis

Affiliations

Soon will be listed here.

Abstract

Freshwater mussels are integral components of riverine ecosystems, influencing water quality, nutrient cycling, and habitat characteristics. Enigmatic freshwater mussel declines, often characterized by sudden mass mortality events, pose significant challenges to conservation efforts. The Clinch River, a freshwater biodiversity hotspot in Virginia and Tennessee, USA, has experienced several enigmatic mass mortality events since 2016. Studies have reported bacteria associated with moribund Pheasantshell (Actinonaias pectorosa) during mortality events in the Clinch River, specifically Yokenella regensburgei. Despite reports of bacterial infection, little is known about their role as pathogens. Through a multiyear case-control study, combining in-situ experiments, field surveys, histology, bacterial isolation, and high-throughput sequencing, we assessed the role of bacteria in Pheasantshell (Actinonais pectorosa) mortality at three sites in the Clinch River. Between May 2021 and December 2023, we collected 21 wild moribund free-living A. pectorosa and 68 hatchery-reared A. pectorosa maintained in silos at the same sites and investigated differences in pathology and microbiologye between groups. No silo mussels presented clinical signs of disease, or gross or microscopic lesions associated with pathological conditions leading to mortality. Our findings reveal a significant association between Yokenella regensburgei and severe multisystemic and multifocal infiltrative hemocytosis with necrosis, consistent with sepsis. Lesions associated with yokenellosis were of sufficient severity and physiological significance to explain mortality in infected hosts. Although our study does not explain the cause of these infections, it confirms that mussels at our study sites are ultimately dying with an infectious disease and that Y. regensburgei can be pathogenic in free-living mussels. Our results underscore the importance of considering bacterial diseases in wild mussel populations and emphasize the need for further research to elucidate the epidemiology and pathogenicity of Y. regensburgei. Overall, our study highlights the importance of integrated approaches combining pathology, microbiology, and epidemiology in freshwater mussel conservation efforts.

Citing Articles

Freshwater Mussel Viromes Increase Rapidly in Diversity and Abundance When Hosts Are Released from Captivity into the Wild.

Richard J, Lane T, Agbalog R, Colletti S, Leach T, Dunn C Animals (Basel). 2024; 14(17).

PMID: 39272316 PMC: 11393864. DOI: 10.3390/ani14172531.

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