Ciliary flows in corals ventilate target areas of high photosynthetic oxygen production

Research output: Contribution to journal › Journal article › Research › peer-review

Standard

Ciliary flows in corals ventilate target areas of high photosynthetic oxygen production. / Pacherres, Cesar O.; Ahmerkamp, Soeren; Koren, Klaus; Richter, Claudio; Holtappels, Moritz.

In: Current Biology, Vol. 32, No. 19, 2022, p. 4150-4158.e3.

Research output: Contribution to journal › Journal article › Research › peer-review

Harvard

Pacherres, CO, Ahmerkamp, S, Koren, K, Richter, C & Holtappels, M 2022, 'Ciliary flows in corals ventilate target areas of high photosynthetic oxygen production', Current Biology, vol. 32, no. 19, pp. 4150-4158.e3. https://doi.org/10.1016/j.cub.2022.07.071

APA

Pacherres, C. O., Ahmerkamp, S., Koren, K., Richter, C., & Holtappels, M. (2022). Ciliary flows in corals ventilate target areas of high photosynthetic oxygen production. Current Biology, 32(19), 4150-4158.e3. https://doi.org/10.1016/j.cub.2022.07.071

Vancouver

Pacherres CO, Ahmerkamp S, Koren K, Richter C, Holtappels M. Ciliary flows in corals ventilate target areas of high photosynthetic oxygen production. Current Biology. 2022;32(19):4150-4158.e3. https://doi.org/10.1016/j.cub.2022.07.071

Author

Pacherres, Cesar O. ; Ahmerkamp, Soeren ; Koren, Klaus ; Richter, Claudio ; Holtappels, Moritz. / Ciliary flows in corals ventilate target areas of high photosynthetic oxygen production. In: Current Biology. 2022 ; Vol. 32, No. 19. pp. 4150-4158.e3.

Bibtex

@article{abc5c3c35cf944c1b1ae86d7af61b03e,

title = "Ciliary flows in corals ventilate target areas of high photosynthetic oxygen production",

abstract = "Most tropical corals live in symbiosis with Symbiodiniaceae algae whose photosynthetic production of oxygen (O2) may lead to excess O2 in the diffusive boundary layer (DBL) above the coral surface. When flow is low, cilia-induced mixing of the coral DBL is vital to remove excess O2 and prevent oxidative stress that may lead to coral bleaching and mortality. Here, we combined particle image velocimetry using O2-sensitive nanoparticles (sensPIV) with chlorophyll (Chla)-sensitive hyperspectral imaging to visualize the microscale distribution and dynamics of ciliary flows and O2 in the coral DBL in relation to the distribution of Symbiodiniaceae Chla in the tissue of the reef building coral, Porites lutea. Curiously, we found an inverse relation between O2 in the DBL and Chla in the underlying tissue, with patches of high O2 in the DBL above low Chla in the underlying tissue surrounding the polyp mouth areas and pockets of low O2 concentrations in the DBL above high Chla in the coenosarc tissue connecting neighboring polyps. The spatial segregation of Chla and O2 is related to ciliary-induced flows, causing a lateral redistribution of O2 in the DBL. In a 2D transport-reaction model of the coral DBL, we show that the enhanced O2 transport allocates parts of the O2 surplus to areas containing less chla, which minimizes oxidative stress. Cilary flows thus confer a spatially complex mass transfer in the coral DBL, which may play an important role in mitigating oxidative stress and bleaching in corals.",

keywords = "boundary layer, chlorophyll, cilia, flow dynamics, oxygen flux, Symbiodinium",

author = "Pacherres, {Cesar O.} and Soeren Ahmerkamp and Klaus Koren and Claudio Richter and Moritz Holtappels",

note = "Publisher Copyright: {\textcopyright} 2022 The Author(s)",

year = "2022",

doi = "10.1016/j.cub.2022.07.071",

language = "English",

volume = "32",

pages = "4150--4158.e3",

journal = "Current Biology",

issn = "0960-9822",

publisher = "Cell Press",

number = "19",

}

RIS

TY - JOUR

T1 - Ciliary flows in corals ventilate target areas of high photosynthetic oxygen production

AU - Pacherres, Cesar O.

AU - Ahmerkamp, Soeren

AU - Koren, Klaus

AU - Richter, Claudio

AU - Holtappels, Moritz

PY - 2022

Y1 - 2022

N2 - Most tropical corals live in symbiosis with Symbiodiniaceae algae whose photosynthetic production of oxygen (O2) may lead to excess O2 in the diffusive boundary layer (DBL) above the coral surface. When flow is low, cilia-induced mixing of the coral DBL is vital to remove excess O2 and prevent oxidative stress that may lead to coral bleaching and mortality. Here, we combined particle image velocimetry using O2-sensitive nanoparticles (sensPIV) with chlorophyll (Chla)-sensitive hyperspectral imaging to visualize the microscale distribution and dynamics of ciliary flows and O2 in the coral DBL in relation to the distribution of Symbiodiniaceae Chla in the tissue of the reef building coral, Porites lutea. Curiously, we found an inverse relation between O2 in the DBL and Chla in the underlying tissue, with patches of high O2 in the DBL above low Chla in the underlying tissue surrounding the polyp mouth areas and pockets of low O2 concentrations in the DBL above high Chla in the coenosarc tissue connecting neighboring polyps. The spatial segregation of Chla and O2 is related to ciliary-induced flows, causing a lateral redistribution of O2 in the DBL. In a 2D transport-reaction model of the coral DBL, we show that the enhanced O2 transport allocates parts of the O2 surplus to areas containing less chla, which minimizes oxidative stress. Cilary flows thus confer a spatially complex mass transfer in the coral DBL, which may play an important role in mitigating oxidative stress and bleaching in corals.

AB - Most tropical corals live in symbiosis with Symbiodiniaceae algae whose photosynthetic production of oxygen (O2) may lead to excess O2 in the diffusive boundary layer (DBL) above the coral surface. When flow is low, cilia-induced mixing of the coral DBL is vital to remove excess O2 and prevent oxidative stress that may lead to coral bleaching and mortality. Here, we combined particle image velocimetry using O2-sensitive nanoparticles (sensPIV) with chlorophyll (Chla)-sensitive hyperspectral imaging to visualize the microscale distribution and dynamics of ciliary flows and O2 in the coral DBL in relation to the distribution of Symbiodiniaceae Chla in the tissue of the reef building coral, Porites lutea. Curiously, we found an inverse relation between O2 in the DBL and Chla in the underlying tissue, with patches of high O2 in the DBL above low Chla in the underlying tissue surrounding the polyp mouth areas and pockets of low O2 concentrations in the DBL above high Chla in the coenosarc tissue connecting neighboring polyps. The spatial segregation of Chla and O2 is related to ciliary-induced flows, causing a lateral redistribution of O2 in the DBL. In a 2D transport-reaction model of the coral DBL, we show that the enhanced O2 transport allocates parts of the O2 surplus to areas containing less chla, which minimizes oxidative stress. Cilary flows thus confer a spatially complex mass transfer in the coral DBL, which may play an important role in mitigating oxidative stress and bleaching in corals.

KW - boundary layer

KW - chlorophyll

KW - cilia

KW - flow dynamics

KW - oxygen flux

KW - Symbiodinium

U2 - 10.1016/j.cub.2022.07.071

DO - 10.1016/j.cub.2022.07.071

M3 - Journal article

C2 - 36002003

AN - SCOPUS:85139313658

VL - 32

SP - 4150-4158.e3

JO - Current Biology

JF - Current Biology

SN - 0960-9822

IS - 19

ER -

ID: 332621628

Department of Biology