Abstract
BackgroundThe lucinid clam Loripes orbiculatus lives in a nutritional symbiosis with sulphur-oxidizing bacteria housed in its gills. Although our understanding of the lucinid endosymbiont physiology and metabolism has made significant progress, relatively little is known about how the host regulates the symbiosis at the genetic and molecular levels. We generated transcriptomes from four L. orbiculatus organs (gills, foot, visceral mass, and mantle) for differential expression analyses, to better understand this clam’s physiological adaptations to a chemosymbiotic lifestyle, and how it regulates nutritional and immune interactions with its symbionts.ResultsThe transcriptome profile of the symbiont-housing gill suggests the regulation of apoptosis and innate immunity are important processes in this organ. We also identified many transcripts encoding ion transporters from the solute carrier family that possibly allow metabolite exchange between host and symbiont. Despite the clam holobiont’s clear reliance on chemosynthesis, the clam’s visceral mass, which contains the digestive tract, is characterised by enzymes involved in digestion, carbohydrate recognition and metabolism, suggesting that L. orbiculatus has a mixotrophic diet. The foot transcriptome is dominated by the biosynthesis of glycoproteins for the construction of mucus tubes, and receptors that mediate the detection of chemical cues in the environment.ConclusionsThe transcriptome profiles of gills, mantle, foot and visceral mass provide insights into the molecular basis underlying the functional specialisation of bivalve organs adapted to a chemosymbiotic lifestyle.
Highlights
The lucinid clam Loripes orbiculatus lives in a nutritional symbiosis with sulphur-oxidizing bacteria housed in its gills
The symbiosis between lucinid clams and sulphuroxidising bacteria is a nutritional strategy; the symbionts use reduced sulphur compounds – produced by organic matter decomposing in anoxic sediment – as electron donors and autotrophically fix carbon dioxide to synthesise organic compounds that are transferred to the host [1]
The lucinid foot constructs tubes burrowing into the sediments below the animal to mine pockets of dissolved sulphide associated with decaying organic matter or the insoluble iron sulphides attached to sediment, in order to support the sulphide-requiring metabolism of their endosymbionts [7]
Summary
The lucinid clam Loripes orbiculatus lives in a nutritional symbiosis with sulphur-oxidizing bacteria housed in its gills. The lucinid foot constructs tubes burrowing into the sediments below the animal to mine pockets of dissolved sulphide associated with decaying organic matter or the insoluble iron sulphides attached to sediment, in order to support the sulphide-requiring metabolism of their endosymbionts [7]. These unusual morphological adaptations to a chemosymbiotic lifestyle have allowed lucinids to successfully exploit the deep layers of sulphiderich sediment, an ecological niche inaccessible to most other animals
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