Khurshid B, Lesniewska E, Polacchi L, L'Héronde M, Jackson DJ, Motreuil S, Thomas J, Bardeau JF, Wolf S, Vielzeuf D, Perrin J, Marin F (2023)
Publication Type: Journal article
Publication year: 2023
DOI: 10.1016/j.actbio.2023.07.028
Spatial localizing of skeletal proteins in biogenic minerals remains a challenge in biomineralization research. To address this goal, we developed a novel in situ mapping technique based on molecular recognition measurements via atomic force microscopy (AFM), which requires three steps: (1) the development and purification of a polyclonal antibody elicited against the target protein, (2) its covalent coupling to a silicon nitride AFM tip ('functionalization'), and (3) scanning of an appropriately prepared biomineral surface. We applied this approach to a soluble shell protein - accripin11 - recently identified as a major component of the calcitic prisms of the fan mussel Pinna nobilis [1]. Multiple tests reveal that accripin11 is evenly distributed at the surface of the prisms and also present in the organic sheaths surrounding the calcitic prisms, indicating that this protein is both intra- and inter-crystalline. We observed that the adhesion force in transverse sections is about twice higher than in longitudinal sections, suggesting that accripin11 may exhibit preferred orientation in the biomineral. To our knowledge, this is the first time that a protein is localized by molecular recognition atomic force microscopy with antibody-functionalized tips in a biogenic mineral. The 'pros' and 'cons' of this methodology are discussed in comparison with more 'classical' approaches like immunogold. This technique, which leaves the surface to analyze clean, might prove useful for clinical tests on non-pathological (bone, teeth) or pathological (kidney stone) biomineralizations. Studies using implants with protein-doped calcium phosphate coating can also benefit from this technology. Statement of significance: Our paper deals with an unconventional technical approach for localizing proteins that are occluded in biominerals. This technique relies on the use of molecular recognition atomic force microscopy with antibody-functionalized tips. Although such approach has been employed in other system, this is the very first time that it is developed for biominerals. In comparison to more classical approaches (such as immunogold), AFM microscopy with antibody-functionalized tips allows higher magnification and keeps the scanned surface clean for other biophysical characterizations. Our method has a general scope as it can be applied in human health, for non-pathological (bone, teeth) and pathological (kidney stone) biomineralizations as well as for bone implants coated with protein-doped calcium phosphate.
APA:
Khurshid, B., Lesniewska, E., Polacchi, L., L'Héronde, M., Jackson, D.J., Motreuil, S.,... Marin, F. (2023). In situ mapping of biomineral skeletal proteins by molecular recognition imaging with antibody-functionalized AFM tips. Acta Biomaterialia. https://dx.doi.org/10.1016/j.actbio.2023.07.028
MLA:
Khurshid, Benazir, et al. "In situ mapping of biomineral skeletal proteins by molecular recognition imaging with antibody-functionalized AFM tips." Acta Biomaterialia (2023).
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