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Protein sequences bound to mineral surfaces persist into deep time

2016; eLife Sciences Publications Ltd; Volume: 5; Linguagem: Inglês

10.7554/elife.17092

2050-084X

Beatrice Demarchi, Shaun Hall, Teresa Roncal‐Herrero, Colin L. Freeman, Jos Woolley, Molly Crisp, Julie Wilson, Anna K. Fotakis, Román Fischer, Benedikt M. Kessler, Rosa Jersie-Christensen, Jesper V. Olsen, James Haile, Jessica E. Thomas, Curtis W. Marean, John Parkington, Samantha Presslee, Julia A. Lee‐Thorp, Peter Ditchfıeld, Jacqueline F. Hamilton, Martyn W. Ward, Chunting Michelle Wang, Marvin Shaw, Terry Harrison, Manuel Domínguez-Rodrigo, R. D. E. MacPhee, Amandus Kwekason, Michaela Ecker, Liora Kolska Horwitz, Michael Chazan, Roland Kröger, Jane Thomas‐Oates, John H. Harding, Enrico Cappellini, Kirsty Penkman, Matthew J. Collins,

Pleistocene-Era Hominins and Archaeology

Proteins persist longer in the fossil record than DNA, but the longevity, survival mechanisms and substrates remain contested. Here, we demonstrate the role of mineral binding in preserving the protein sequence in ostrich (Struthionidae) eggshell, including from the palaeontological sites of Laetoli (3.8 Ma) and Olduvai Gorge (1.3 Ma) in Tanzania. By tracking protein diagenesis back in time we find consistent patterns of preservation, demonstrating authenticity of the surviving sequences. Molecular dynamics simulations of struthiocalcin-1 and -2, the dominant proteins within the eggshell, reveal that distinct domains bind to the mineral surface. It is the domain with the strongest calculated binding energy to the calcite surface that is selectively preserved. Thermal age calculations demonstrate that the Laetoli and Olduvai peptides are 50 times older than any previously authenticated sequence (equivalent to ~16 Ma at a constant 10°C).