Abalone withering syndrome: distribution, impacts, current diagnostic methods and new findings.

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Abalone withering syndrome: distribution, impacts, current diagnostic methods and new findings.

Dis Aquat Organ. 2014 Apr 3;108(3):261-270

Authors: Crosson LM, Wight N, Vanblaricom GR, Kiryu I, Moore JD, Friedman CS

Abstract
Withering syndrome (WS) is a fatal disease of abalone caused by a Rickettsiales-like organism (WS-RLO). The causative agent, ‘Candidatus Xenohaliotis californiensis’, occurs along the eastern Pacific margin of North America in California, USA, and Baja California, Mexico. However, as infected abalones have been transported to Chile, China, Taiwan, Iceland, Ireland, Israel, Spain, Thailand and Japan, the geographical range of the etiological agent is suspected to be broad, especially where California red abalones Haliotis rufescens are cultured or in areas where native species have been exposed to this species. Susceptibility varies among species, with up to 99% losses of black abalone H. cracherodii in laboratory and field studies in the USA to no losses among the small abalone H. diversicolor supertexta in Thailand. Some populations that have suffered catastrophic losses due to WS have developed resistance to the disease. In addition, a newly identified phage hyperparasite of the WS-RLO may reduce pathogenicity and dampen associated losses. Diagnosis of WS requires the identification of infection with the pathogen (WS-RLO detected via in situ hybridization or histology coupled with PCR and sequence analysis) accompanied by morphological changes that characterize this disease (e.g. pedal and digestive gland atrophy, and digestive gland metaplasia). A quantitative PCR assay was developed and may be useful in quantifying pathogen DNA. Confirmation of infection cannot be done by PCR analysis alone but can be used as a proxy for infection in areas where the agent is established and is recommended for inclusion in health examinations. Avoidance of WS is best accomplished by the establishment of a health history and multiple health examinations prior to movement of animals.

PMID: 24695239 [PubMed – as supplied by publisher]

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Reduced disease in black abalone following mass mortality: phage therapy and natural selection.

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Reduced disease in black abalone following mass mortality: phage therapy and natural selection.

Front Microbiol. 2014;5:78

Authors: Friedman CS, Wight N, Crosson LM, Vanblaricom GR, Lafferty KD

Abstract
Black abalone, Haliotis cracherodii, populations along the NE Pacific ocean have declined due to the rickettsial disease withering syndrome (WS). Natural recovery on San Nicolas Island (SNI) of Southern California suggested the development of resistance in island populations. Experimental challenges in one treatment demonstrated that progeny of disease-selected black abalone from SNI survived better than did those from naïve black abalone from Carmel Point in mainland coastal central California. Unexpectedly, the presence of a newly observed bacteriophage infecting the WS rickettsia (WS-RLO) had strong effects on the survival of infected abalone. Specifically, presence of phage-infected RLO (RLOv) reduced the host response to infection, RLO infection loads, and associated mortality. These data suggest that the black abalone: WS-RLO relationship is evolving through dual host mechanisms of resistance to RLO infection in the digestive gland via tolerance to infection in the primary target tissue (the post-esophagus) coupled with reduced pathogenicity of the WS-RLO by phage infection, which effectively reduces the infection load in the primary target tissue by half. Sea surface temperature patterns off southern California, associated with a recent hiatus in global-scale ocean warming, do not appear to be a sufficient explanation for survival patterns in SNI black abalone. These data highlight the potential for natural recovery of abalone populations over time and that further understanding of mechanisms governing host-parasite relationships will better enable us to manage declining populations.

PMID: 24672512 [PubMed]

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