Adsorptive exchange of coccolith biominerals facilitates viral infection
Johns, C.T.; Bondoc-Naumovitz, K.G.; Matthews, A.; Matson, P.G.; Iglesias-Rodriguez, M.D.; Taylor, A.R.; Fuchs, H.L.; Bidle, K.D. (2023). Adsorptive exchange of coccolith biominerals facilitates viral infection. Science Advances 9(3): eadc8728. https://dx.doi.org/10.1126/sciadv.adc8728
In: Science Advances. AAAS: New York. ISSN 2375-2548; e-ISSN 2375-2548, meer
|   |
| Auteurs | | Top |
- Johns, C.T.
- Bondoc-Naumovitz, K.G.
- Matthews, A.
- Matson, P.G.
|
- Iglesias-Rodriguez, M.D.
- Taylor, A.R.
- Fuchs, H.L.
- Bidle, K.D.
|
|
| Abstract |
Marine coccolithophores are globally distributed, unicellular phytoplankton that produce nanopatterned, calcite biominerals (coccoliths). These biominerals are synthesized internally, deposited into an extracellular coccosphere, and routinely released into the external medium, where they profoundly affect the global carbon cycle. The cellular costs and benefits of calcification remain unresolved. Here, we show observational and experimental evidence, supported by biophysical modeling, that free coccoliths are highly adsorptive biominerals that readily interact with cells to form chimeric coccospheres and with viruses to form “viroliths,” which facilitate infection. Adsorption to cells is mediated by organic matter associated with the coccolith base plate and varies with biomineral morphology. Biomineral hitchhiking increases host-virus encounters by nearly an order of magnitude and can be the dominant mode of infection under stormy conditions, fundamentally altering how we view biomineral-cell-virus interactions in the environment. |
|
