Macromolecules in brachiopod shells: characterization and diagenesis

Collins, Matthew J.; Muyzer, Gerard; Curry, Gordon B.; Sandberg, Philip A.; Westbroek, Peter

doi:10.1111/j.1502-3931.1991.tb01491.x

Cited by 37 publications

(24 citation statements)

References 30 publications

(9 reference statements)

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“…However, remains of organic matrices within the older skeletal parts can sometimes be still preserved, as shown by the very rare occurrence of the amide I band in some spectra of Leptastraea and the quite common presence of carbon measured in the calcification centers of Lobophyllia. Several previous works deal with degradation of soluble intraskeletal organic matrices extracted from fossil carbonate skeletons, including mollusks, brachiopods, corals, and sponges from various ages (Ivanov et al 1972;van der Meide et al 1980;Collins et al 1991;Gautret and Marin 1993;Gautret and Aubert 1993;Gautret 2001). Although involving different time spans, these studies have shown a gradational decrease of the amount of soluble intraskeletal matrices which can be extracted from fossils of increasing ages by comparison with their living counterparts.…”

Section: Differential Diagenetic History Of Organic and Mineral Compomentioning

confidence: 98%

Earliest Steps of Diagenesis in Living Scleractinian Corals: Evidence from Ultrastructural Pattern and Raman Spectroscopy

Perrin¹,

Smith²

2007

Journal of Sedimentary Research

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The precise understanding of diagenetic pathways occurring during fossilization of biomineralized skeletons is of critical importance for various related fields in both paleontology and sedimentology. In particular, this may have fundamental implications in paleoenvironmental studies for interpreting geochemical proxies extracted from these skeletons.The effects of the first diagenetic processes on both mineral and organic compounds present in skeletons of scleractinian corals were investigated in two different coral colonies (Lobophyllia corymbosa and Leptastraea purpurea) by combining mapping of skeletal ultrastructural patterns by SEM and in situ analysis by Raman microspectroscopy. The two elementary ultrastructural features typical of scleractinian corals, the centers of calcification and the sets of aragonite fibers, have been characterized in the uppermost parts (i.e. the ''living zone'') of both coral colonies. Diagenetic features affecting the skeleton itself and also represented by fibrous diagenetic cements have been analyzed in the oldest basal parts of each colony. All Raman spectra display several vibrational bands typical of aragonite (but no calcite). Additionally, several Raman bands indicate the presence of organic compounds, some of which likely characterize proteinous components, and provide the first in situ chemical record of the skeletal organic matrices. Tentative assignments to CH, CH 2 , CH 3 , NH 2 , CHO, CNC, and SO groups are proposed. In the ''living zone,'' some of these bands are different in the two coral species. In Raman spectra measured in the oldest skeletal parts of both colonies, these bands decrease markedly in number and diversity or even disappear, indicating that significant decay of intraskeletal organic matrices does occur in just a few years. Therefore, early diagenesis in these skeletons results from the interaction between the degradation of organic matrices and the diagenetic processes affecting the skeletal aragonite submicron-size crystals.

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Section: Differential Diagenetic History Of Organic and Mineral Compomentioning

confidence: 98%

Earliest Steps of Diagenesis in Living Scleractinian Corals: Evidence from Ultrastructural Pattern and Raman Spectroscopy

Perrin¹,

Smith²

2007

Journal of Sedimentary Research

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“…[30] Caramelization, well known in cooking, involves anhydrous reactions between sugars and amino acids in Maillard-type condensations to form melanoidin compounds. Melanoidins have been reported in fossil molluscs and brachiopods [69,70] and are important in the formation of humic acids and kerogens. [71] The reaction of proteins with saccharides to form melanoidin www.advancedsciencenews.com www.bioessays-journal.com complexes may also explain the preservation of skin in human bog bodies.…”

Section: The Molecular Composition Of Tissues and Their Decay Environmentioning

confidence: 99%

Soft‐Bodied Fossils Are Not Simply Rotten Carcasses – Toward a Holistic Understanding of Exceptional Fossil Preservation

et al. 2017

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Exceptionally preserved fossils are the product of complex interplays of biological and geological processes including burial, autolysis and microbial decay, authigenic mineralization, diagenesis, metamorphism, and finally weathering and exhumation. Determining which tissues are preserved and how biases affect their preservation pathways is important for interpreting fossils in phylogenetic, ecological, and evolutionary frameworks. Although laboratory decay experiments reveal important aspects of fossilization, applying the results directly to the interpretation of exceptionally preserved fossils may overlook the impact of other key processes that remove or preserve morphological information. Investigations of fossils preserving nonbiomineralized tissues suggest that certain structures that are decay resistant (e.g., the notochord) are rarely preserved (even where carbonaceous components survive), and decay-prone structures (e.g., nervous systems) can fossilize, albeit rarely. As we review here, decay resistance is an imperfect indicator of fossilization potential, and a suite of biological and geological processes account for the features preserved in exceptional fossils.

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“…Compositional differences between sediment size and density fractions are well known [77,79,80], but more work is needed in order to characterize the relative lability of specific organic substances associated with these different fractions. Organic matter that is incorporated into silicate and carbonate tests during biological deposition of these minerals is better preserved than cellular organic matter: mineral-bound amino acids are well protected from diagenesis and remain relatively unaltered chemically [86,87] compared to cellular amino acids. In a study of opal-rich Southern Ocean sediments, Ingalls et al [88] showed that the proportion of silica-bound amino acids increased significantly with increasing depth in the sediments, reaching > 50% of total hydrolyzable amino 4 Correlation between mineral surface area and total organic carbon content of marine sediments collected from a the Washington continental margin and b the California continental margin.…”

Section: Matrix Effectsmentioning

confidence: 99%

Degradation and Preservation of Organic Matter in Marine Sediments

Wakeham

Canuel

The Handbook of Environmental Chemistry

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Macromolecules in brachiopod shells: characterization and diagenesis

Cited by 37 publications

References 30 publications

Earliest Steps of Diagenesis in Living Scleractinian Corals: Evidence from Ultrastructural Pattern and Raman Spectroscopy

Earliest Steps of Diagenesis in Living Scleractinian Corals: Evidence from Ultrastructural Pattern and Raman Spectroscopy

Soft‐Bodied Fossils Are Not Simply Rotten Carcasses – Toward a Holistic Understanding of Exceptional Fossil Preservation

Degradation and Preservation of Organic Matter in Marine Sediments

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