Cyanobacterial calcification is promoted by CO(2)-Concentrating mechanisms (CCMs) developed in response to photosynthetic carbon limitation. Changes in atmospheric composition (CO(2) fall, O(2) rise) near the Devonian-Mississippian transition (ca. 360 Ma) were sufficiently large to induce CCMs in cyanobacteria. Cyanobacterial sheath calcification significantly increased during the Mississippian, ca. 325-355 Ma. It is proposed that these atmospheric changes triggered cyanobacteria to induce CCMs-previously developed during a large CO(2) decline in the Proterozoic-and that this promoted their calcification. CCMs in phytoplankton stimulate primary productivity by increasing photosynthetic efficiency and ameliorating carbon limitation. Phytoplankton community restructuring in favor of groups that possessed effective CCMs but had poor body-fossil records, such as picoplanktic cyanobacteria, could account for Late Devonian acritarch decline and the subsequent apparent scarcity of phytoplankton in the late Paleozoic (the so-called phytoplankton blackout). This is supported by biomarkers indicating an increase in cyanobacteria at the Devonian-Mississippian transition and by carbon isotope values and black shale deposition that, despite acritarch decline, reflect increased primary productivity. The Mississippian episode of cyanobacterial calcification was relatively short lived. Calcification declined ca. 325 Ma, before the end of the Mississippian, as a continued decline in CO(2) lowered seawater carbonate saturation. The induction of cyanobacterial CCMs, triggered by Late Devonian change to a relatively low CO(2) and high O(2) atmosphere, has probably persisted to the present day, but well-developed calcification in marine cyanobacteria has been restricted to intervals of elevated carbonate saturation state.

• 出版日期2009-10