Immune response of the Caribbean sea fan, Gorgonia ventalina, exposed to an Aplanochytrium parasite as revealed by transcriptome sequencing.

Colleen A Burge,C Drew Harvell,Steven Roberts,Morgan E Mouchka

doi:10.3389/fphys.2013.00180

Colleen A Burge, C Drew Harvell + Show 2 more

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https://doi.org/10.3389/fphys.2013.00180

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Abstract

Coral reef communities are undergoing marked declines due to a variety of stressors including disease. The sea fan coral, Gorgonia ventalina, is a tractable study system to investigate mechanisms of immunity to a naturally occurring pathogen. Functional studies in Gorgonia ventalina immunity indicate that several key pathways and cellular components are involved in response to natural microbial invaders, although to date the functional and regulatory pathways remain largely un-described. This study used short-read sequencing (Illumina GAIIx) to identify genes involved in the response of G. ventalina to a naturally occurring Aplanochytrium spp. parasite. De novo assembly of the G. ventalina transcriptome yielded 90,230 contigs of which 40,142 were annotated. RNA-Seq analysis revealed 210 differentially expressed genes in sea fans exposed to the Aplanochytrium parasite. Differentially expressed genes involved in immunity include pattern recognition molecules, anti-microbial peptides, and genes involved in wound repair and reactive oxygen species formation. Gene enrichment analysis indicated eight biological processes were enriched representing 36 genes, largely involved with protein translation and energy production. This is the first report using high-throughput sequencing to characterize the host response of a coral to a natural pathogen. Furthermore, we have generated the first transcriptome for a soft (octocoral or non-scleractinian) coral species. Expression analysis revealed genes important in invertebrate innate immune pathways, as well as those whose role is previously un-described in cnidarians. This resource will be valuable in characterizing G. ventalina immune response to infection and co-infection of pathogens in the context of environmental change.

Highlights

Infectious diseases, caused by a variety of pathogens, are contributing to the decline of coral reefs worldwide by threatening biodiversity, causing marked population declines, and changing community structure (Harvell et al, 2002)
Sequences corresponding to all 118 orthologs conserved across metazoans as identified in OrthoDB (Waterhouse et al, 2011) were identified in the G. ventalina transcriptome
IMMUNE GENES AND ROLE IN CNIDARIAN IMMUNITY We identified a number of immune-related genes that were differentially expressed between control and Aplanochytriumexposed sea fans, including those that code for proteins involved in pattern recognition molecules, antimicrobial peptides, and wound repair

Summary

Introduction

Infectious diseases, caused by a variety of pathogens, are contributing to the decline of coral reefs worldwide (reviewed by Sutherland et al, 2004; Harvell et al, 2007; Bourne et al, 2009) by threatening biodiversity, causing marked population declines, and changing community structure (Harvell et al, 2002). The response to pathogen exposure or disease in G. ventalina has focused on measurement of effector enzymes (e.g., prophenoloxidase, peroxidase, chitinase, catalase, and antifungal and antibacterial peptides) (Douglas et al, 2007; Mydlarz and Harvell, 2007; Couch et al, 2008; Mydlarz et al, 2008) and pathological responses using histology (Petes et al, 2003; Mydlarz et al, 2008; Burge et al, 2012a) These studies demonstrate cellular and systemic responses that play a critical role in sea fan immune function.

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