Your search keyword '"Rickaby RE"' showing total 22 results

1. Rapid diversification underlying the global dominance of a cosmopolitan phytoplankton

Author

Bendif, EM, Probert, I, Archontikis, OA, Young, JR, Beaufort, L, Rickaby, RE, Filatov, D, Centre européen de recherche et d'enseignement des géosciences de l'environnement (CEREGE), and Institut de Recherche pour le Développement (IRD)-Institut National de la Recherche Agronomique (INRA)-Aix Marseille Université (AMU)-Collège de France (CdF (institution))-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)

Subjects

[SDE]Environmental Sciences, population genetics, microbial biooceanography, phylogenomics, [SDV.BID]Life Sciences [q-bio]/Biodiversity, Microbiology, Ecology, Evolution, Behavior and Systematics

Abstract

Marine phytoplankton play important roles in the global ecosystem, with a limited number of cosmopolitan keystone species driving their biomass. Recent studies have revealed that many of these phytoplankton are complexes composed of sibling species, but little is known about the evolutionary processes underlying their formation. Gephyrocapsa huxleyi, a widely distributed and abundant unicellular marine planktonic algae, produces calcified scales (coccoliths), thereby significantly affects global biogeochemical cycles via sequestration of inorganic carbon. This species is composed of morphotypes defined by differing degrees of coccolith calcification, the evolutionary ecology of which remains unclear. Here, we report an integrated morphological, ecological and genomic survey across globally distributed G. huxleyi strains to reconstruct evolutionary relationships between morphotypes in relation to their habitats. While G. huxleyi has been considered a single cosmopolitan species, our analyses demonstrate that it has evolved to comprise at least three distinct species, which led us to formally revise the taxonomy of the G. huxleyi complex. Moreover, the first speciation event occurred before the onset of the last interglacial period (~140 ka), while the second followed during this interglacial. Then, further rapid diversifications occurred during the most recent ice-sheet expansion of the last glacial period and established morphotypes as dominant populations across environmental clines. These results suggest that glacial-cycle dynamics contributed to the isolation of ocean basins and the segregations of oceans fronts as extrinsic drivers of micro-evolutionary radiations in extant marine phytoplankton.

Published

2023

2. The origin of carbon isotope vital effects in coccolith calcite.

Author

McClelland HL, Bruggeman J, Hermoso M, and Rickaby RE

Abstract

Calcite microfossils are widely used to study climate and oceanography in Earth's geological past. Coccoliths, readily preserved calcite plates produced by a group of single-celled surface-ocean dwelling algae called coccolithophores, have formed a significant fraction of marine sediments since the Late Triassic. However, unlike the shells of foraminifera, their zooplankton counterparts, coccoliths remain underused in palaeo-reconstructions. Precipitated in an intracellular chemical and isotopic microenvironment, coccolith calcite exhibits large and enigmatic departures from the isotopic composition of abiogenic calcite, known as vital effects. Here we show that the calcification to carbon fixation ratio determines whether coccolith calcite is isotopically heavier or lighter than abiogenic calcite, and that the size of the deviation is determined by the degree of carbon utilization. We discuss the theoretical potential for, and current limitations of, coccolith-based CO 2 paleobarometry, that may eventually facilitate use of the ubiquitous and geologically extensive sedimentary archive.

Published

2017

3. The uronic acid content of coccolith-associated polysaccharides provides insight into coccolithogenesis and past climate.

Author

Lee RB, Mavridou DA, Papadakos G, McClelland HL, and Rickaby RE

Subjects

Adaptation, Physiological, Calcification, Physiologic, Calcium Carbonate history, Calcium Carbonate metabolism, Carbon history, Carbon metabolism, Carbon Dioxide chemistry, Carbon Dioxide history, Carbon Dioxide metabolism, Crystallization, Fossils history, Haptophyta classification, Haptophyta metabolism, History, Ancient, Paleontology, Phytoplankton classification, Phytoplankton metabolism, Polysaccharides history, Polysaccharides metabolism, Species Specificity, Uronic Acids history, Uronic Acids metabolism, Calcium Carbonate chemistry, Carbon chemistry, Haptophyta chemistry, Phytoplankton chemistry, Polysaccharides chemistry, Uronic Acids chemistry

Abstract

Unicellular phytoplanktonic algae (coccolithophores) are among the most prolific producers of calcium carbonate on the planet, with a production of ∼10 26 coccoliths per year. During their lith formation, coccolithophores mainly employ coccolith-associated polysaccharides (CAPs) for the regulation of crystal nucleation and growth. These macromolecules interact with the intracellular calcifying compartment (coccolith vesicle) through the charged carboxyl groups of their uronic acid residues. Here we report the isolation of CAPs from modern day coccolithophores and their prehistoric predecessors and we demonstrate that their uronic acid content (UAC) offers a species-specific signature. We also show that there is a correlation between the UAC of CAPs and the internal saturation state of the coccolith vesicle that, for most geologically abundant species, is inextricably linked to carbon availability. These findings suggest that the UAC of CAPs reports on the adaptation of coccolithogenesis to environmental changes and can be used for the estimation of past CO 2 concentrations.

Published

2016

4. Calcification response of a key phytoplankton family to millennial-scale environmental change.

Author

McClelland HL, Barbarin N, Beaufort L, Hermoso M, Ferretti P, Greaves M, and Rickaby RE

Abstract

Coccolithophores are single-celled photosynthesizing marine algae, responsible for half of the calcification in the surface ocean, and exert a strong influence on the distribution of carbon among global reservoirs, and thus Earth's climate. Calcification in the surface ocean decreases the buffering capacity of seawater for CO 2 , whilst photosynthetic carbon fixation has the opposite effect. Experiments in culture have suggested that coccolithophore calcification decreases under high CO 2 concentrations ([CO 2 (aq)]) constituting a negative feedback. However, the extent to which these results are representative of natural populations, and of the response over more than a few hundred generations is unclear. Here we describe and apply a novel rationale for size-normalizing the mass of the calcite plates produced by the most abundant family of coccolithophores, the Noëlaerhabdaceae. On average, ancient populations subjected to coupled gradual increases in [CO 2 (aq)] and temperature over a few million generations in a natural environment become relatively more highly calcified, implying a positive climatic feedback. We hypothesize that this is the result of selection manifest in natural populations over millennial timescales, so has necessarily eluded laboratory experiments.

Published

2016

5. Why marine phytoplankton calcify.

Author

Monteiro FM, Bach LT, Brownlee C, Bown P, Rickaby RE, Poulton AJ, Tyrrell T, Beaufort L, Dutkiewicz S, Gibbs S, Gutowska MA, Lee R, Riebesell U, Young J, and Ridgwell A

Subjects

Calcium Carbonate chemistry, Ecosystem, Global Warming, Hydrogen-Ion Concentration, Oceans and Seas, Photosynthesis, Seawater chemistry, Calcification, Physiologic physiology, Haptophyta metabolism

Abstract

Calcifying marine phytoplankton-coccolithophores- are some of the most successful yet enigmatic organisms in the ocean and are at risk from global change. To better understand how they will be affected, we need to know "why" coccolithophores calcify. We review coccolithophorid evolutionary history and cell biology as well as insights from recent experiments to provide a critical assessment of the costs and benefits of calcification. We conclude that calcification has high energy demands and that coccolithophores might have calcified initially to reduce grazing pressure but that additional benefits such as protection from photodamage and viral/bacterial attack further explain their high diversity and broad spectrum ecology. The cost-benefit aspect of these traits is illustrated by novel ecosystem modeling, although conclusive observations remain limited. In the future ocean, the trade-off between changing ecological and physiological costs of calcification and their benefits will ultimately decide how this important group is affected by ocean acidification and global warming.

Published

2016

6. Harry Elderfield (1943-2016).

Author

Rickaby RE

Subjects

Animal Shells chemistry, Animals, Carbon Cycle, Climate Change history, Foraminifera chemistry, Geologic Sediments analysis, History, 20th Century, History, Ancient, Oceans and Seas, Seawater analysis, Strontium Radioisotopes analysis, United Kingdom, Geologic Sediments chemistry, Seawater chemistry

Published

2016

7. Large variation in the Rubisco kinetics of diatoms reveals diversity among their carbon-concentrating mechanisms.

Author

Young JN, Heureux AM, Sharwood RE, Rickaby RE, Morel FM, and Whitney SM

Subjects

Diatoms enzymology, Kinetics, Photosynthesis, Phytoplankton enzymology, Phytoplankton metabolism, Carbon metabolism, Diatoms metabolism, Ribulose-Bisphosphate Carboxylase metabolism

Abstract

While marine phytoplankton rival plants in their contribution to global primary productivity, our understanding of their photosynthesis remains rudimentary. In particular, the kinetic diversity of the CO2-fixing enzyme, Rubisco, in phytoplankton remains unknown. Here we quantify the maximum rates of carboxylation (k cat (c)), oxygenation (k cat (o)), Michaelis constants (K m) for CO2 (K C) and O2 (K O), and specificity for CO2 over O2 (SC/O) for Form I Rubisco from 11 diatom species. Diatom Rubisco shows greater variation in K C (23-68 µM), SC/O (57-116mol mol(-1)), and K O (413-2032 µM) relative to plant and algal Rubisco. The broad range of K C values mostly exceed those of C4 plant Rubisco, suggesting that the strength of the carbon-concentrating mechanism (CCM) in diatoms is more diverse, and more effective than previously predicted. The measured k cat (c) for each diatom Rubisco showed less variation (2.1-3.7s(-1)), thus averting the canonical trade-off typically observed between K C and k cat (c) for plant Form I Rubisco. Uniquely, a negative relationship between K C and cellular Rubisco content was found, suggesting variation among diatom species in how they allocate their limited cellular resources between Rubisco synthesis and their CCM. The activation status of Rubisco in each diatom was low, indicating a requirement for Rubisco activase. This work highlights the need to better understand the correlative natural diversity between the Rubisco kinetics and CCM of diatoms and the underpinning mechanistic differences in catalytic chemistry among the Form I Rubisco superfamily., (© The Author 2016. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2016

8. Erratum: Oxygen depletion recorded in upper waters of the glacial Southern Ocean.

Author

Lu Z, Hoogakker BA, Hillenbrand CD, Zhou X, Thomas E, Gutchness KM, Lu W, Jones L, and Rickaby RE

Published

2016

9. Oxygen depletion recorded in upper waters of the glacial Southern Ocean.

Author

Lu Z, Hoogakker BA, Hillenbrand CD, Zhou X, Thomas E, Gutchess KM, Lu W, Jones L, and Rickaby RE

Abstract

Oxygen depletion in the upper ocean is commonly associated with poor ventilation and storage of respired carbon, potentially linked to atmospheric CO2 levels. Iodine to calcium ratios (I/Ca) in recent planktonic foraminifera suggest that values less than ∼2.5 μmol mol(-1) indicate the presence of O2-depleted water. Here we apply this proxy to estimate past dissolved oxygen concentrations in the near surface waters of the currently well-oxygenated Southern Ocean, which played a critical role in carbon sequestration during glacial times. A down-core planktonic I/Ca record from south of the Antarctic Polar Front (APF) suggests that minimum O2 concentrations in the upper ocean fell below 70 μmol kg(-1) during the last two glacial periods, indicating persistent glacial O2 depletion at the heart of the carbon engine of the Earth's climate system. These new estimates of past ocean oxygenation variability may assist in resolving mechanisms responsible for the much-debated ice-age atmospheric CO2 decline.

Published

2016

10. Goldilocks and the three inorganic equilibria: how Earth's chemistry and life coevolve to be nearly in tune.

Author

Rickaby RE

Abstract

Life and the chemical environment are united in an inescapable feedback cycle. The periodic table of the elements essential for life has transformed over Earth's history, but, as today, evolved in tune with the elements available in abundance in the environment. The most revolutionary time in life's history was the advent and proliferation of oxygenic photosynthesis which forced the environment towards a greater degree of oxidation. Consideration of three inorganic chemical equilibria throughout this gradual oxygenation prescribes a phased release of trace metals to the environment, which appear to have coevolved with employment of these new chemicals by life. Evolution towards complexity was chemically constrained, and changes in availability of notably Fe, Zn and Cu paced the systematic development of complex organisms. Evolving life repeatedly catalysed its own chemical challenges via the unwitting release of new and initially toxic chemicals. Ultimately, the harnessing of these allowed life to advance to greater complexity, though the mechanism responsible for translating novel chemistry to heritable use remains elusive. Whether a chemical acts as a poison or a nutrient lies both in the dose and in its environmental history., (© 2015 The Author(s) Published by the Royal Society. All rights reserved.)

Published

2015

11. Thermal, trophic and metabolic life histories of inaccessible fishes revealed from stable-isotope analyses: a case study using orange roughy Hoplostethus atlanticus.

Author

Trueman CN, Rickaby RE, and Shephard S

Subjects

Animals, Atlantic Ocean, Fishes physiology, Ireland, Isotopes analysis, Life Cycle Stages, Muscles chemistry, Otolithic Membrane chemistry, Ecosystem, Fishes metabolism

Abstract

A time-resolved record of inhabited water depth, metabolic rate and trophic behaviour of the orange roughy Hoplostethus atlanticus was recovered from combined stable-isotope analyses of otolith and muscle tissue. The results demonstrate that H. atlanticus from the north-east Atlantic Ocean have a complex life history with three distinct depth-stratified life stages. Early juvenile H. atlanticus occupy relatively shallow habitats, juvenile H. atlanticus show a deep-demersal phase, rising at sexual maturity, and adult H. atlanticus exploit increasingly deep habitats with increasing age. At all sampled sizes, H. atlanticus muscle tissues have an isotopic composition suggesting a benthic rather than benthopelagic or pelagic diet. Isotopic measures of relative metabolic rate provide an insight into energy partitioning throughout ontogeny. Hoplostethus atlanticus have relatively low metabolic rates compared to coexisting deep-water benthic fishes, consistent with their unusually high longevity. Surprisingly, lifetime fastest growth rates are achieved during juvenile stages when otolith isotopes imply deep-water residency and relatively low metabolic rates. Fast growth may be sustained during a period of high efficiency associated with reduced metabolic costs of prey capture or predator evasion. The stable-isotope approach can be applied to any teleost and provides a rapid, cost-effective technique for studying deep-water fish communities., (© 2013 The Fisheries Society of the British Isles.)

Published

2013

12. Reply to Morel: Cadmium as a micronutrient and macrotoxin in the oceans.

Author

Horner TJ, Lee RB, Henderson GM, and Rickaby RE

Subjects

Cadmium analysis, Cadmium metabolism, Carbonic Anhydrases metabolism, Seawater analysis

Published

2013

13. Nonspecific uptake and homeostasis drive the oceanic cadmium cycle.

Author

Horner TJ, Lee RB, Henderson GM, and Rickaby RE

Subjects

Cadmium isolation & purification, Electrophoresis, Polyacrylamide Gel, Escherichia coli metabolism, Histidine chemistry, Isotopes analysis, Oceans and Seas, Phosphates analysis, Cadmium analysis, Cadmium metabolism, Carbonic Anhydrases metabolism, Seawater analysis

Abstract

The global marine distributions of Cd and phosphate are closely correlated, which has led to Cd being considered as a marine micronutrient, despite its toxicity to life. The explanation for this nutrient-like behavior is unknown because there is only one identified biochemical function for Cd, an unusual Cd/Zn carbonic anhydrase. Recent developments in Cd isotope mass spectrometry have revealed that Cd uptake by phytoplankton causes isotopic fractionation in the open ocean and in culture. Here we investigate the physiochemical pathways that fractionate Cd isotopes by performing subcellular Cd isotope analysis on genetically modified microorganisms. We find that expression of the Cd/Zn carbonic anhydrase makes no difference to the Cd isotope composition of whole cells. Instead, a large proportion of the Cd is partitioned into cell membranes with a similar direction and magnitude of Cd isotopic fractionation to that seen in surface seawater. This observation is well explained if Cd is mistakenly imported with other divalent metals and subsequently managed by binding within the cell to avoid toxicity. This process may apply to other divalent metals, whereby nonspecific uptake and subsequent homeostasis may contribute to elemental and isotopic distributions in seawater, even for elements commonly considered as micronutrients.

Published

2013

14. Cloning, Expression and Characterization of the δ-carbonic Anhydrase of Thalassiosira weissflogii (Bacillariophyceae).

Author

Lee RB, Smith JA, and Rickaby RE

Abstract

Carbonic anhydrase (CA) is a ubiquitous metalloenzyme responsible for accelerating the interconversion of CO2 and bicarbonate. Although CAs are involved in a broad range of biochemical processes involving carboxylation or decarboxylation reactions, they are of special interest due to their role in photosynthetic CO2 assimilation in marine phytoplankton, especially under low-CO2 conditions. Several phylogenetically independent classes of CAs have been identified in a variety of marine phytoplankton. TWCA1, first discovered in Thalassiosira weissflogii (Grunow) G. Fryxell & Hasle, is the founding member of the δ-class of CAs; these appear to be extracellular enzymes, but are still relatively poorly characterized. To date, it has remained uncertain whether TWCA1 possesses true CA activity due to the difficulty in producing a functional protein in a heterologous expression system. Herein we describe the fusion of a full-length open reading frame of TWCA1 to the coding sequence of a self-splicing intein in a pTWIN2 expression vector that has allowed successful production of a functional enzyme in Escherichia coli. Assay of the recombinant protein shows that TWCA1 is a catalytically active δ-CA possessing both CO2 hydration and esterase activity., (© 2012 Phycological Society of America.)

Published

2013

15. Adaptive signals in algal Rubisco reveal a history of ancient atmospheric carbon dioxide.

Author

Young JN, Rickaby RE, Kapralov MV, and Filatov DA

Subjects

Base Sequence, Bayes Theorem, DNA, Plant genetics, Genes, Plant, Haptophyta classification, Haptophyta enzymology, Haptophyta genetics, Molecular Sequence Data, Oxygen chemistry, Photosynthesis, Phylogeny, Rhodophyta classification, Rhodophyta genetics, Ribulose-Bisphosphate Carboxylase classification, Ribulose-Bisphosphate Carboxylase genetics, Selection, Genetic, Time Factors, Adaptation, Physiological, Atmosphere chemistry, Carbon Dioxide chemistry, Rhodophyta enzymology, Ribulose-Bisphosphate Carboxylase chemistry

Abstract

Rubisco, the most abundant enzyme on the Earth and responsible for all photosynthetic carbon fixation, is often thought of as a highly conserved and sluggish enzyme. Yet, different algal Rubiscos demonstrate a range of kinetic properties hinting at a history of evolution and adaptation. Here, we show that algal Rubisco has indeed evolved adaptively during ancient and distinct geological periods. Using DNA sequences of extant marine algae of the red and Chromista lineage, we define positive selection within the large subunit of Rubisco, encoded by rbcL, to occur basal to the radiation of modern marine groups. This signal of positive selection appears to be responding to changing intracellular concentrations of carbon dioxide (CO(2)) triggered by physiological adaptations to declining atmospheric CO(2). Within the ecologically important Haptophyta (including coccolithophores) and Bacillariophyta (diatoms), positive selection occurred consistently during periods of falling Phanerozoic CO(2) and suggests emergence of carbon-concentrating mechanisms. During the Proterozoic, a strong signal of positive selection after secondary endosymbiosis occurs at the origin of the Chromista lineage (approx. 1.1 Ga), with further positive selection events until 0.41 Ga, implying a significant and continuous decrease in atmospheric CO(2) encompassing the Cryogenian Snowball Earth events. We surmise that positive selection in Rubisco has been caused by declines in atmospheric CO(2) and hence acts as a proxy for ancient atmospheric CO(2).

Published

2012

16. Interaction of the coccolithophore Gephyrocapsa oceanica with its carbon environment: response to a recreated high-CO2 geological past.

Author

Moolna A and Rickaby RE

Subjects

Adaptation, Physiological, Calcium metabolism, Photosynthesis, Carbon metabolism, Haptophyta growth & development, Haptophyta metabolism, Seawater chemistry, Seawater microbiology

Abstract

Coccolithophores have played a key role in the carbon cycle since becoming dominant in the Cretaceous ocean, and their influence depends fundamentally on how they interact with their external carbon environment. Because the photosynthetic carbon-fixing enzyme Rubisco requires high levels of CO(2) for effective catalysis, coccolithophores are known to induce carbon concentrating mechanisms (CCMs) to raise the level of dissolved inorganic carbon (DIC) in an 'internal pool'. The ocean carbon system has varied greatly over the geological past, suggesting that coccolithophore interactions with that external carbon environment will have changed in parallel. The widespread present-day coccolithophore Gephyrocapsa oceanica was acclimated here to a geological scale change in the seawater carbon system (five times higher DIC and alkalinity). Significant acclimation in response to the external carbon environment was demonstrated by a fourfold increase in the K(m) substrate concentration requirement for half-maximum photosynthetic carbon fixation rates (suggesting that CCMs were down-regulated when ambient carbon was more available). There was, however, no difference in growth rate, morphology or calcification, suggesting that calcification is not coupled to photosynthesis as one of the CCMs induced here and that productivity (growth rate and calcification) is not carbon-limited under representative present-day conditions. Beyond the kinetic parameters of photosynthesis, the only other indication of changed cell physiology seen was the increased fractionation of carbon isotopes into organic matter. These findings demonstrate that G. oceanica changes its carbon-use physiology to maintain consistent photosynthetic carbon fixation in concert with different levels of ambient DIC without changing its morphology or calcification., (© 2011 Blackwell Publishing Ltd.)

Published

2012

17. Sensitivity of coccolithophores to carbonate chemistry and ocean acidification.

Author

Beaufort L, Probert I, de Garidel-Thoron T, Bendif EM, Ruiz-Pino D, Metzl N, Goyet C, Buchet N, Coupel P, Grelaud M, Rost B, Rickaby RE, and de Vargas C

Subjects

Aquatic Organisms chemistry, Aquatic Organisms metabolism, Atmosphere chemistry, Body Weight, Calcium metabolism, Calcium Carbonate chemistry, Calcium Carbonate metabolism, Carbon Cycle, Carbon Dioxide analysis, Carbon Dioxide chemistry, Carbonic Acid chemistry, Fossils, Geologic Sediments chemistry, Haptophyta chemistry, Hydrogen-Ion Concentration, Molecular Sequence Data, Oceans and Seas, Pacific Ocean, Partial Pressure, Photosynthesis, Phytoplankton chemistry, Calcification, Physiologic, Calcium Carbonate analysis, Carbonic Acid analysis, Haptophyta metabolism, Phytoplankton metabolism, Seawater chemistry

Abstract

About one-third of the carbon dioxide (CO(2)) released into the atmosphere as a result of human activity has been absorbed by the oceans, where it partitions into the constituent ions of carbonic acid. This leads to ocean acidification, one of the major threats to marine ecosystems and particularly to calcifying organisms such as corals, foraminifera and coccolithophores. Coccolithophores are abundant phytoplankton that are responsible for a large part of modern oceanic carbonate production. Culture experiments investigating the physiological response of coccolithophore calcification to increased CO(2) have yielded contradictory results between and even within species. Here we quantified the calcite mass of dominant coccolithophores in the present ocean and over the past forty thousand years, and found a marked pattern of decreasing calcification with increasing partial pressure of CO(2) and concomitant decreasing concentrations of CO(3)(2-). Our analyses revealed that differentially calcified species and morphotypes are distributed in the ocean according to carbonate chemistry. A substantial impact on the marine carbon cycle might be expected upon extrapolation of this correlation to predicted ocean acidification in the future. However, our discovery of a heavily calcified Emiliania huxleyi morphotype in modern waters with low pH highlights the complexity of assemblage-level responses to environmental forcing factors.

Published

2011

18. Migration of the subtropical front as a modulator of glacial climate.

Author

Bard E and Rickaby RE

Subjects

Amoeba metabolism, Animals, Antarctic Regions, Atlantic Ocean, Atmosphere chemistry, Carbon Dioxide metabolism, Cold Climate, Cold Temperature, Geologic Sediments microbiology, Indian Ocean, Oxygen Isotopes, Pacific Ocean, Partial Pressure, Plankton metabolism, Salinity, Seawater chemistry, South Africa, Tropical Climate, Climate, Ice Cover, Water Movements

Abstract

Ice cores extracted from the Antarctic ice sheet suggest that glacial conditions, and the relationship between isotopically derived temperatures and atmospheric PCO(2) have been constant over the last 800,000 years of the Late Pleistocene epoch. But independent lines of evidence, such as the extent of Northern Hemisphere ice sheets, sea level and other temperature records, point towards a fluctuating severity of glacial periods, particularly during the more extreme glacial stadials centred around 340,000 and 420,000 years ago (marine isotope stages 10 and 12). Previously unidentified mechanisms therefore appear to have mediated the relationship between insolation, CO(2) and climate. Here we test whether northward migration of the subtropical front (STF) off the southeastern coast of South Africa acts as a gatekeeper for the Agulhas current, which controls the transport of heat and salt from the Indo-Pacific Ocean to the Atlantic Ocean. Using a new 800,000-year record of sea surface temperature and ocean productivity from ocean sediment core MD962077, we demonstrate that during cold stadials (particularly marine isotope stages 10 and 12), productivity peaked and sea surface temperature was up to 6 degrees C cooler than modern temperatures. This suggests that during these cooler stadials, the STF moved northward by up to 7 degrees latitude, nearly shutting off the Agulhas current. Our results, combined with faunal assemblages from the south Atlantic show that variable northwards migration of the Southern Hemisphere STF can modulate the severity of each glacial period by altering the strength of the Agulhas current carrying heat and salt to the Atlantic meridional overturning circulation. We show hence that the degree of northwards migration of the STF can partially decouple global climate from atmospheric partial pressure of carbon dioxide, P CO(2), and help to resolve the long-standing puzzle of differing glacial amplitudes within a consistent range of atmospheric PCO(2).

Published

2009

19. Phytoplankton calcification in a high-CO2 world.

Author

Iglesias-Rodriguez MD, Halloran PR, Rickaby RE, Hall IR, Colmenero-Hidalgo E, Gittins JR, Green DR, Tyrrell T, Gibbs SJ, von Dassow P, Rehm E, Armbrust EV, and Boessenkool KP

Subjects

Atmosphere, Calcium Carbonate analysis, Eukaryota growth & development, Geologic Sediments chemistry, Hydrogen-Ion Concentration, Oceans and Seas, Photosynthesis, Phytoplankton growth & development, Calcification, Physiologic, Carbon Dioxide, Eukaryota physiology, Phytoplankton physiology

Abstract

Ocean acidification in response to rising atmospheric CO2 partial pressures is widely expected to reduce calcification by marine organisms. From the mid-Mesozoic, coccolithophores have been major calcium carbonate producers in the world's oceans, today accounting for about a third of the total marine CaCO3 production. Here, we present laboratory evidence that calcification and net primary production in the coccolithophore species Emiliania huxleyi are significantly increased by high CO2 partial pressures. Field evidence from the deep ocean is consistent with these laboratory conclusions, indicating that over the past 220 years there has been a 40% increase in average coccolith mass. Our findings show that coccolithophores are already responding and will probably continue to respond to rising atmospheric CO2 partial pressures, which has important implications for biogeochemical modeling of future oceans and climate.

Published

2008

20. Cool La Niña during the warmth of the Pliocene?

Author

Rickaby RE and Halloran P

Abstract

The role of El Niño-Southern Oscillation (ENSO) in greenhouse warming and climate change remains controversial. During the warmth of the early-mid Pliocene, we find evidence for enhanced thermocline tilt and cold upwelling in the equatorial Pacific, consistent with the prevalence of a La Niña-like state, rather than the proposed persistent warm El Niño-like conditions. Our Pliocene paleothermometer supports the idea of a dynamic "ocean thermostat" in which heating of the tropical Pacific leads to a cooling of the east equatorial Pacific and a La Niña-like state, analogous to observations of a transient increasing east-west sea surface temperature gradient in the 20th-century tropical Pacific.

Published

2005

21. Biogeochemistry of carbonates: recorders of past oceans and climate.

Author

Rickaby RE and Schrag DP

Subjects

Animals, Biochemical Phenomena, Carbonates chemistry, Geological Phenomena, Oceans and Seas, Biochemistry, Carbonates metabolism, Climate, Geology

Abstract

Trace metal proxies bound within the calcium carbonate tests of oceanic organisms provide a unique insight into how the climate system works on timescales which span eight orders of magnitude, from annual to hundreds of millions of years. Whilst the motivation for developing these proxies was the idea that thermodynamic equilibria control the chemistry during precipitation, in reality the application of trace metal proxies relies upon empirical calibration. Such calibration can be applied to a wide range of environmental reconstructions, but more accurate application of proxies requires a mechanistic understanding of the biomineralization process. The partitioning of trace metals into biogenic carbonates reflects to some extent the same pattern as an inorganic crystal, but there is an additional selectivity and differing environmental sensitivity to, e.g., temperature, which confirms that biochemical processes also play a role in the uptake and assembly of ions into a crystal. Different organisms display differing degrees of biological control on their carbonate chemistry. Aragonitic coral chemistry is most similar to inorganic precipitation from seawater whilst coccolithophores are most different, and these contrasts correlate with the degree of control of the organism over its biomineralization. Selectivity between Ca and trace metals during biomineralization arises during transport by pumps, channels, or nucleation upon an organic matrix. The biological selectivity of the transporters and matrix is strikingly similar in its base chemistry to the selective assembly of ions into a crystal. In each case, the selectivity between Ca2+ and trace metals derives from the balance between the energy required for dehydration of the hexaaqua complex of the cation, and the energy released from the new coordination geometry of binding with either carbonyl oxygen from polysaccharides or amino acids, or carbonate oxygen in the crystal. This is a speculative idea, but with some careful chemical calculations based on the energy of binding of Ca2+ or the trace metal ions to these macromolecular structures, it provides an alternative thermodynamic framework within which to consider the application of trace metal proxies.

Published

2005

22. Oceanic Cd/P ratio and nutrient utilization in the glacial Southern Ocean

Author

Elderfield H and Rickaby RE

Abstract

During glacial periods, low atmospheric carbon dioxide concentration has been associated with increased oceanic carbon uptake, particularly in the southern oceans. The mechanism involved remains unclear. Because ocean productivity is strongly influenced by nutrient levels, palaeo-oceanographic proxies have been applied to investigate nutrient utilization in surface water across glacial transitions. Here we show that present-day cadmium and phosphorus concentrations in the global oceans can be explained by a chemical fractionation during particle formation, whereby uptake of cadmium occurs in preference to uptake of phosphorus. This allows the reconstruction of past surface water phosphate concentrations from the cadmium/calcium ratio of planktonic foraminifera. Results from the Last Glacial Maximum show similar phosphate utilization in the subantarctic to that of today, but much smaller utilization in the polar Southern Ocean, in a model that is consistent with the expansion of glacial sea ice and which can reconcile all proxy records of polar nutrient utilization. By restricting communication between the ocean and atmosphere, sea ice expansion also provides a mechanism for reduced CO2 release by the Southern Ocean and lower glacial atmospheric CO2.

Published

2000