Journal
GEOSCIENCES
Volume 2, Issue 4, Pages 235-259Publisher
MDPI
DOI: 10.3390/geosciences2040235
Keywords
stromatolite; oxygen; photosynthesis; cyanobacteria; morphogenesis; Archean; evolution
Categories
Funding
- NSF [EAR-0843358]
- NASA Astrobiology Institute [NNA08CN84A]
- NASA [NNA08CN84A, 103831] Funding Source: Federal RePORTER
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Some modern filamentous oxygenic photosynthetic bacteria (cyanobacteria) form macroscopic tufts, laminated cones and ridges that are very similar to some Archean and Proterozoic stromatolites. However, it remains unclear whether microbes that constructed Archean clumps, tufts, cones and ridges also produced oxygen. Here, we address this question by examining the physiology of cyanobacterial clumps, aggregates similar to 0.5 mm in diameter that initiate the growth of modern mm-and cm-scale cones. Clumps contain more particulate organic carbon in the form of denser, bowed and bent cyanobacterial filaments, abandoned sheaths and non-cyanobacterial cells relative to the surrounding areas. Increasing concentrations of oxygen in the solution enhance the bending of filaments and the persistence of clumps by reducing the lateral migration of filaments away from clumps. Clumped mats in oxic media also release less glycolate, a soluble photorespiration product, and retain a larger pool of carbon in the mat. Clumping thus benefits filamentous mat builders whose incorporation of inorganic carbon is sensitive to oxygen. The morphogenetic sequence of mm-scale clumps, reticulate ridges and conical stromatolites from the 2.7 Ga Tumbiana Formation likely records similar O-2-dependent behaviors, preserving currently the oldest morphological signature of oxygenated environments on Early Earth.
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