This study highlights the potential of ocean calcifiers to
sequester atmospheric carbon in quantity and even reverse climate change. The
study, which we hope will show why cultivating calcifiers in the short term
would be advantageous, attempts to provide a different, biological, viewpoint
of the published data bearing on two specific issues, namely ocean
acidification and return of CO2 to the atmosphere by the calcification reaction
itself. We find reasons to doubt the validity of both issues. Experiments
showing ocean acidification is damaging to calcifiers have all used
experimental pH levels that are not projected to be reached in the oceans until
the next century or later; today’s oceans are alkaline. In open water habitats
in equilibrium with the atmosphere, it may be true to claim precipitation of
CaCO3 by calcification as a net source of atmospheric CO2, but only if the
solidified limestone is ignored as sequestered CO2. In these kinds of
conditions, the calcification response is not carried out by living calcifiers.
The chemistry of life is distinguished from that of open water by occurring on
enzyme polypeptide surfaces, inside organelles with phospholipid membranes that
selectively absorb certain ions, and inside cells encased in phospholipid
bilayer membranes. Nowadays, marine calcifiers (coccolithophore algae,
Foraminifera [protists], Mollusca, Crustacea, Anthozoa [corals], Echinodermata
and some annelids) convert atmospheric carbon dioxide (CO2) into solid calcium
carbonate (CaCO3) protective shells which are left when they die. These
organisms could be the biotechnological carbon capture and storage mechanism to
control climate change. Ignoring what is known about the biology, physiology,
and molecular biology of living calcifiers leads to erroneous conclusions and
deficient advice about the potential for calcifier biotechnology to contribute
to atmosphere remediation. We conclude that the world’s aquaculture industries
already operate biotechnology that, with massive and immediate global
expansion, can sustainably control atmospheric CO2 levels at a reasonable cost.
We hope that this view of marine calcifiers will show the value and promise of
the contribution that aquaculture could make to bringing equilibrium to the
atmosphere.
Author(s) Details:
David Moore,
Department of Biology, Medicine and Health, School of Biological
Sciences, The University of Manchester, UK.
Matthias Heilweck,
Independent Researcher, F-68240, Kaysersberg, France.
William Burton Fears,
Department of Medicine, Southwestern Medical School, Dallas, Texas and
Founding Fellow of the American College of Endocrinology, USA.
Peter Petros
Kaapa Biotech Oy, Teilinummentie 4, 09120 Karjalohja, Finland.
Samuel J Squires,
Department of Biology, Medicine and Health, The University of Manchester, UK.
Elena Tamburini
Department of Environmental and Prevention Sciences, University of Ferrara,
Ferrara, Italy.
Robert Paul Waldron
Independent Researcher, LA-70448, Mandeville, Louisiana, USA.
Please see the link here: https://stm.bookpi.org/IBS-V6/article/view/14929
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