https://delcampolab.com/tag/biomineralisation/BiomineralisationHugo Blox Builder (https://hugoblox.com)en-usSun, 30 Jun 2024 00:00:00 +0000https://delcampolab.com/media/logo_hu3705697567409936087.pnghttps://delcampolab.com/tag/biomineralisation/https://delcampolab.com/project/marine-animals/Sun, 30 Jun 2024 00:00:00 +0000https://delcampolab.com/project/marine-animals/<p>We study the microbial communities associated with marine model organisms, combining metabarcoding, genomics, and transcriptomics to understand how microbiomes contribute to host physiology and the broader ocean carbon cycle.</p> <h3 id="biomineralisation-in-the-gulf-toadfish-microbiome">Biomineralisation in the Gulf Toadfish microbiome</h3> <p>Marine teleost fish precipitate CaCO₃ in their intestines as part of their osmoregulatory strategy, a process that may account for up to 15% of total calcium carbonate deposition in the ocean. Despite its significance, the molecular mechanisms driving this reaction remain unknown — no candidate genes have been identified in the fish genome or transcriptome of the Gulf Toadfish (<em>Opsanus beta</em>), the primary model for studying this process.</p> <p>We are testing the hypothesis that gut microbiota — rather than the fish itself — are responsible for intestinal carbonate precipitation. Bacteria are well-established agents of calcium carbonate deposition in marine environments, and their role in analogous processes (such as kidney stone formation) has been documented in mammals. Using a combination of 16S/18S metabarcoding, metagenomics, and transcriptomics, we are characterising the microbial communities of the toadfish gut and identifying candidate bacteria driving CaCO₃ deposition. Understanding this process is critical for accurate modelling of ocean carbon dynamics and for exploring marine microbiome-based carbon sequestration strategies.</p> <p><strong>Key publications</strong></p> <p>Oehlert AM, Garza J, Nixon S, et al., including <strong>Javier del Campo</strong> &amp; Grosell M (2024). <a href="https://www.sciencedirect.com/science/article/abs/pii/S0048969724000299" target="_blank" rel="noopener">Implications of dietary carbon incorporation in fish carbonates for the global carbon cycle</a>. <em>Science of the Total Environment</em>, 916, 169895.</p> <p>Preprint: <a href="https://www.biorxiv.org/content/10.1101/2025.10.07.681008" target="_blank" rel="noopener">Symbiotic bacteria support calcium carbonate precipitation in the Gulf Toadfish gut</a>. <em>bioRxiv</em> (2025).</p> <hr> <h3 id="the-microbiome-of-the-california-sea-hare">The microbiome of the California sea hare</h3> <div style="position: relative; display: inline-block; width: 100%;"> <img src="aplysia.png" style="width: 100%; display: block;"> <span style="position: absolute; bottom: 0; right: 0; background: rgba(0,0,0,0.5); color: #fff; padding: 3px 8px; font-size: 0.78em; line-height: 1.6;">Photo by Elizabeth Whitson</span> </div> <p>The California sea hare, <em>Aplysia californica</em>, is a well-studied model organism in neurobiology and neuroscience. Despite deep knowledge of its physiology, anatomy, and ethology, little is known about its microbiome. In collaboration with the National Resource for <em>Aplysia</em> at the Rosenstiel School of Marine and Atmospheric Science, we are exploring for the first time the prokaryotic and microeukaryotic communities associated with this organism using a genomic, metabarcoding approach. These data will allow us to investigate how the microbiome influences behaviour, ageing, and other characteristics of this important model animal.</p>