Primary Utricle Structure of Six Halimeda Species and Potential Relevance for Ocean Acidification Tolerance

Variations in utricle morphology may be responsible for different tolerances to ocean acidification (OA) within the macroalgal genus Halimeda, an important sediment producer on reefs. However, differences in species’ utricle morphology and their relationship to calcification and crystal formation ha...

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Bibliographic Details
Main Authors: Peach, Katherine E., Koch, Marguerite S., Blackwelder, Patricia, Guerrero-Given, Debbie, Kamasawa, Naomi
Format: Article in Journal/Newspaper
Language:unknown
Published: NSUWorks 2017
Subjects:
Aragonite
Diffusion pathway
Halimeda
Microstructure
Ultrastructure
Marine Biology
Oceanography and Atmospheric Sciences and Meteorology
Ocean acidification
Online Access:https://nsuworks.nova.edu/occ_facarticles/789
https://nsuworks.nova.edu/cgi/viewcontent.cgi?article=1798&context=occ_facarticles
Description
Summary:Variations in utricle morphology may be responsible for different tolerances to ocean acidification (OA) within the macroalgal genus Halimeda, an important sediment producer on reefs. However, differences in species’ utricle morphology and their relationship to calcification and crystal formation have not been well articulated. In the present study, we characterized the utricle morphologies of six Halimeda species. Primary utricle ultrastructure was quantitatively and qualitatively compared to tissue inorganic content and crystal microstructure. Morphologies differed across species and several morphometric relationships were revealed. Primary utricle size (r2=0.70) and diffusion pathway length (r2=0.87) had inverse relationships with inorganic content based on regression analyses, and corresponded to crystal microstructure form. Species with large utricles and long diffusion pathways contained more narrow (~0.15 μm) aragonite needles and minimal micro-anhedral crystal formations. In contrast, species with small utricles and short diffusion pathways elucidated aggregates of micro-anhedral crystals and wider aragonite needles (~0.30 μm). Species’ utricle characteristics generally corresponded to specific evolutionary lineages. Thus, characteristics of Halimeda utricle morphology may control long-term adaptive responses to OA, an idea articulated in the broader literature.

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