Your search keyword '"Hydroides elegans"' showing total 4 results

1. Recoverable impacts of ocean acidification on the tubeworm, Hydroides elegans: implication for biofouling in future coastal oceans

Author

Yuan Meng, Kaimin Shih, Haimin Yao, Chaoyi Li, Vengatesen Thiyagarajan, Hangkong Li, and Chong He

Subjects

0301 basic medicine, fungi, 030106 microbiology, Ocean acidification, Aquatic Science, Applied Microbiology and Biotechnology, Biofouling, 03 medical and health sciences, 030104 developmental biology, Oceanography, Hydroides elegans, Environmental science, Calcareous, geographic locations, Water Science and Technology, Biomineralization

Abstract

Ocean uptake of anthropogenic CO2 causes ocean acidification (OA), which not only decreases the calcification rate, but also impairs the formation of calcareous shells or tubes in marine invertebrates such as the dominant biofouling tubeworm species, Hydroides elegans. This study examined the ability of tubeworms to resume normal tube calcification when returned to ambient pH 8.1 from a projected near-future OA level of pH 7.8. Tubeworms produced structurally impaired and mechanically weaker calcareous tubes at pH 7.8 compared to at pH 8.1, but were able to recover when the pH was restored to ambient levels. This suggests that tubeworms can physiologically recover from the impacts of OA on tube calcification, composition, density, hardness and stiffness when returned to optimal conditions. These results help understanding of the progression of biofouling communities dominated by tubeworms in future oceans with low pH induced by OA.

Published

2019

2. Recoverable impacts of ocean acidification on the tubeworm, Hydroides elegans : implication for biofouling in future coastal oceans.

Author

Meng Y, Li C, Li H, Shih K, He C, Yao H, and Thiyagarajan V

Subjects

Acids, Animal Shells chemistry, Animal Shells drug effects, Animals, Aquatic Organisms physiology, Carbon Dioxide toxicity, Forecasting, Hydrogen-Ion Concentration, Oceans and Seas, Polychaeta physiology, Water Pollutants, Chemical toxicity, Aquatic Organisms drug effects, Biofouling prevention & control, Calcification, Physiologic drug effects, Polychaeta drug effects, Seawater chemistry

Abstract

Ocean uptake of anthropogenic CO 2 causes ocean acidification (OA), which not only decreases the calcification rate, but also impairs the formation of calcareous shells or tubes in marine invertebrates such as the dominant biofouling tubeworm species, Hydroides elegans . This study examined the ability of tubeworms to resume normal tube calcification when returned to ambient pH 8.1 from a projected near-future OA level of pH 7.8. Tubeworms produced structurally impaired and mechanically weaker calcareous tubes at pH 7.8 compared to at pH 8.1, but were able to recover when the pH was restored to ambient levels. This suggests that tubeworms can physiologically recover from the impacts of OA on tube calcification, composition, density, hardness and stiffness when returned to optimal conditions. These results help understanding of the progression of biofouling communities dominated by tubeworms in future oceans with low pH induced by OA.

Published

2019

3. Mechanical robustness of the calcareous tubeworm Hydroides elegans: warming mitigates the adverse effects of ocean acidification.

Author

Li C, Meng Y, He C, Chan VB, Yao H, and Thiyagarajan V

Subjects

Animals, Finite Element Analysis, Minerals, Oceans and Seas, Salinity, X-Ray Microtomography methods, Biofouling prevention & control, Global Warming, Hydrogen-Ion Concentration, Polychaeta growth & development, Polychaeta physiology, Seawater analysis, Seawater chemistry, Temperature

Abstract

Development of antifouling strategies requires knowledge of how fouling organisms would respond to climate change associated environmental stressors. Here, a calcareous tube built by the tubeworm, Hydroides elegans, was used as an example to evaluate the individual and interactive effects of ocean acidification (OA), warming and reduced salinity on the mechanical properties of a tube. Tubeworms produce a mechanically weaker tube with less resistance to simulated predator attack under OA (pH 7.8). Warming (29°C) increased tube volume, tube mineral density and the tube's resistance to a simulated predatory attack. A weakening effect by OA did not make the removal of tubeworms easier except for the earliest stage, in which warming had the least effect. Reduced salinity (27 psu) did not affect tubes. This study showed that both mechanical analysis and computational modeling can be integrated with biofouling research to provide insights into how fouling communities might develop in future ocean conditions.

Published

2016

4. Proteomic profiling during the pre-competent to competent transition of the biofouling polychaete Hydroides elegans.

Author

Zhang Y, Sun J, Zhang H, Chandramouli KH, Xu Y, He LS, Ravasi T, and Qian PY

Subjects

Amino Acid Sequence, Animals, Contig Mapping, Gene Expression Profiling, Larva genetics, Larva growth & development, Larva metabolism, Mass Spectrometry, Metamorphosis, Biological, Polychaeta metabolism, Proteome metabolism, Biofouling, Polychaeta genetics, Polychaeta growth & development, Proteome genetics

Abstract

The polychaete, Hydroides elegans, is a tube-building worm that is widely distributed in tropical and subtropical seas. It is a dominant fouling species and thus a major target organism in antifouling research. Here, the first high-throughput proteomic profiling of pre-competent and competent larvae of H. elegans is reported with the identification of 1,519 and 1,322 proteins, respectively. These proteins were associated with a variety of biological processes. However, a large proportion was involved in energy metabolism, redox homeostasis, and microtubule-based processes. A comparative analysis revealed 21 proteins that were differentially regulated in larvae approaching competency.

Published

2014