Your search keyword '"Bosellini FR"' showing total 7 results

1. Are coral reefs victims of their own past success?

Author

Renema, W, Pandolfi, JM, Kiessling, W, Bosellini, FR, Klaus, JS, Korpanty, C, Rosen, BR, Santodomingo, N, Wallace, CC, Webster, JM, Johnson, KG, Renema, W, Pandolfi, JM, Kiessling, W, Bosellini, FR, Klaus, JS, Korpanty, C, Rosen, BR, Santodomingo, N, Wallace, CC, Webster, JM, and Johnson, KG

Abstract

NHM Repository

Published

2016

2. Late Miocene transformation of Mediterranean Sea biodiversity.

Author

Agiadi K, Hohmann N, Gliozzi E, Thivaiou D, Bosellini FR, Taviani M, Bianucci G, Collareta A, Londeix L, Faranda C, Bulian F, Koskeridou E, Lozar F, Mancini AM, Dominici S, Moissette P, Campos IB, Borghi E, Iliopoulos G, Antonarakou A, Kontakiotis G, Besiou E, Zarkogiannis SD, Harzhauser M, Sierro FJ, Coll M, Vasiliev I, Camerlenghi A, and García-Castellanos D

Subjects

Mediterranean Sea, Animals, Ecosystem, Fossils, Biodiversity, Climate Change

Abstract

Understanding deep-time marine biodiversity change under the combined effects of climate and connectivity changes is fundamental for predicting the impacts of modern climate change in semi-enclosed seas. We quantify the Late Miocene-Early Pliocene [11.63 to 3.6 million years (Ma)] taxonomic diversity of the Mediterranean Sea for calcareous nannoplankton, dinocysts, foraminifera, ostracods, corals, molluscs, bryozoans, echinoids, fishes, and marine mammals. During this time, marine biota was affected by global climate cooling and the restriction of the Mediterranean's connection to the Atlantic Ocean that peaked with the Messinian salinity crisis. Although the net change in species richness from the Tortonian to the Zanclean varies by group, species turnover is greater than 30% in all cases, reflecting a high degree of reorganization of the marine ecosystem after the crisis. The results show a clear perturbation already in the pre-evaporitic Messinian (7.25 to 5.97 Ma), with patterns differing among groups and subbasins.

Published

2024

3. The marine biodiversity impact of the Late Miocene Mediterranean salinity crisis.

Author

Agiadi K, Hohmann N, Gliozzi E, Thivaiou D, Bosellini FR, Taviani M, Bianucci G, Collareta A, Londeix L, Faranda C, Bulian F, Koskeridou E, Lozar F, Mancini AM, Dominici S, Moissette P, Campos IB, Borghi E, Iliopoulos G, Antonarakou A, Kontakiotis G, Besiou E, Zarkogiannis SD, Harzhauser M, Sierro FJ, Coll M, Vasiliev I, Camerlenghi A, and García-Castellanos D

Subjects

Animals, Mediterranean Sea, Seawater, Aquatic Organisms, Biodiversity, Fossils, Salinity, Extinction, Biological

Abstract

Massive salt accumulations, or salt giants, have formed in highly restricted marine basins throughout geological history, but their impact on biodiversity has been only patchily studied. The salt giant in the Mediterranean Sea formed as a result of the restriction of its gateway to the Atlantic during the Messinian Salinity Crisis (MSC) 5.97 to 5.33 million years ago. Here, we quantify the biodiversity changes associated with the MSC based on a compilation of the Mediterranean fossil record. We conclude that 86 endemic species of the 2006 pre-MSC marine species survived the crisis, and that the present eastward-decreasing richness gradient in the Mediterranean was established after the MSC.

Published

2024

4. Impact of ocean acidification on crystallographic vital effect of the coral skeleton.

Author

Coronado I, Fine M, Bosellini FR, and Stolarski J

Subjects

Animals, Anthozoa physiology, Calcification, Physiologic, Climate Change, Coral Reefs, Crystallography, X-Ray, Ecosystem, Hydrogen-Ion Concentration, Anthozoa chemistry, Seawater chemistry

Abstract

Distinguishing between environmental and species-specific physiological signals, recorded in coral skeletons, is one of the fundamental challenges in their reliable use as (paleo)climate proxies. To date, characteristic biological bias in skeleton-recorded environmental signatures (vital effect) was shown in shifts in geochemical signatures. Herein, for the first time, we have assessed crystallographic parameters of bio-aragonite to study the response of the reef-building coral Stylophora pistillata to experimental seawater acidification (pH 8.2, 7.6 and 7.3). Skeletons formed under high pCO 2 conditions show systematic crystallographic changes such as better constrained crystal orientation and anisotropic distortions of bio-aragonite lattice parameters due to increased amount of intracrystalline organic matrix and water content. These variations in crystallographic features that seem to reflect physiological adjustments of biomineralizing organisms to environmental change, are herein called crystallographic vital effect (CVE). CVE may register those changes in the biomineralization process that may not yet be perceived at the macromorphological skeletal level.

Published

2019

5. High coral reef connectivity across the Indian Ocean is revealed 6-7 Ma ago by a turbid-water scleractinian assemblage from Tanzania (Eastern Africa).

Author

Reuter M, Bosellini FR, Budd AF, Ćorić S, Piller WE, and Harzhauser M

Abstract

The present centre of coral diversity in the Western Indian Ocean is defined by the northern Mozambique Channel with an extension northward to Mafia Island in Tanzania (Eastern Africa). The geological and evolutionary history of this hotspot of marine biodiversity remains so far completely obscure, because Cenozoic fossil reef communities of this area are not well known. This study presents a new fossil scleractinian fauna from the Mikindani Formation in southern Tanzania. It comprises 16 symbiotic coral taxa of which nine could be identified to the species and five to the genus level. Coral habitat consisted of low-relief biostromes that developed in shallow water at the front of the Rovuma Delta under conditions of variable sediment input. The biostromes are dated to be Messinian based on associated calcareous nannoplankton and planktic foraminifers. The studied coral assemblage shows close affinities with the Recent Western Indian Ocean biogeographic province and Central Indo-West Pacific biogeographic region as well as with the Miocene of Indonesia. Faunistic relations with the Oligocene-early Miocene of Somalia and Iran do not exist. The patterns of species distribution document a major palaeobiogeographic change in the Indian Ocean that correlates with the onset of the Miocene Indian Ocean Equatorial Jet during the middle Miocene. The clear Indonesian affinity of the Messinian coral fauna from southern Tanzania implies that this westerly oceanic surface current provided high biogeographic connectivity across the Indian Ocean during the late Miocene. Today, the coastal waters of Indonesia are located in the Coral Triangle. Diversification of this global epicentre of marine biodiversity started in the early Miocene and it was established already during the middle Miocene. Our results indicate that the East African hotspot of coral biodiversity originated as an offshoot of the Coral Triangle in the middle to late Miocene., Competing Interests: Conflict of interestThe authors declare that they have no conflict of interest., (© The Author(s) 2019.)

Published

2019

6. A unique coral biomineralization pattern has resisted 40 million years of major ocean chemistry change.

Author

Stolarski J, Bosellini FR, Wallace CC, Gothmann AM, Mazur M, Domart-Coulon I, Gutner-Hoch E, Neuser RD, Levy O, Shemesh A, and Meibom A

Subjects

Animals, Anthozoa classification, Anthozoa physiology, Anthozoa ultrastructure, Calcium chemistry, Coral Reefs, Fossils ultrastructure, History, Ancient, Hydrogen-Ion Concentration, Magnesium chemistry, Oceans and Seas, Phylogeny, Temperature, Anthozoa chemistry, Calcification, Physiologic, Carbon Dioxide chemistry, Fossils history, Seawater chemistry

Abstract

Today coral reefs are threatened by changes to seawater conditions associated with rapid anthropogenic global climate change. Yet, since the Cenozoic, these organisms have experienced major fluctuations in atmospheric CO2 levels (from greenhouse conditions of high pCO2 in the Eocene to low pCO2 ice-house conditions in the Oligocene-Miocene) and a dramatically changing ocean Mg/Ca ratio. Here we show that the most diverse, widespread, and abundant reef-building coral genus Acropora (20 morphological groups and 150 living species) has not only survived these environmental changes, but has maintained its distinct skeletal biomineralization pattern for at least 40 My: Well-preserved fossil Acropora skeletons from the Eocene, Oligocene, and Miocene show ultra-structures indistinguishable from those of extant representatives of the genus and their aragonitic skeleton Mg/Ca ratios trace the inferred ocean Mg/Ca ratio precisely since the Eocene. Therefore, among marine biogenic carbonate fossils, well-preserved acroporid skeletons represent material with very high potential for reconstruction of ancient ocean chemistry.

Published

2016

7. Are coral reefs victims of their own past success?

Author

Renema W, Pandolfi JM, Kiessling W, Bosellini FR, Klaus JS, Korpanty C, Rosen BR, Santodomingo N, Wallace CC, Webster JM, and Johnson KG

Subjects

Animals, Climate Change, Humans, Anthozoa growth & development, Coral Reefs, Ecosystem

Abstract

As one of the most prolific and widespread reef builders, the staghorn coral Acropora holds a disproportionately large role in how coral reefs will respond to accelerating anthropogenic change. We show that although Acropora has a diverse history extended over the past 50 million years, it was not a dominant reef builder until the onset of high-amplitude glacioeustatic sea-level fluctuations 1.8 million years ago. High growth rates and propagation by fragmentation have favored staghorn corals since this time. In contrast, staghorn corals are among the most vulnerable corals to anthropogenic stressors, with marked global loss of abundance worldwide. The continued decline in staghorn coral abundance and the mounting challenges from both local stress and climate change will limit the coral reefs' ability to provide ecosystem services.

Published

2016