The intriguing capability of branched glycoprotein filaments to change their hierarchical organization, mediated by external biophysical stimuli, continues to expand understanding of self-assembling strategies that can dynamically rearrange networks at long range. Previous research has explored the corresponding biological, physiological and genetic mechanisms, focusing on protein assemblies within a limited range of nanometric units. Using direct microscopy bio-imaging, we have determined the morpho-structural changes of self-assembled filament networks of the zona pellucida, revealing controlled levels of structured organizations to join distinct evolved stages of the oocyte (Immature, Mature, and Fertilized). This natural soft network reorganizes its corresponding hierarchical network to generate symmetric, asymmetric, and ultimately a state with the lowest asymmetry of the outer surface roughness, and internal pores reversibly changed from elliptical to circular configurations at the corresponding stages. These elusive morpho-structural changes are regulated by the nanostructured polymorphisms of the branched filaments by self-extension/-contraction/-bending processes, modulated by determinate theoretical angles among repetitive filament units. Controlling the nanoscale self-assembling properties by delivering a minimum number of activation bio-signals may be triggered by these specific nanostructured polymorphic organizations. Finally, this research aims to guide this soft biomaterial into a desired state to protect oocytes, eggs, and embryos during development, to favour/prevent the fertilization/polyspermy processes and eventually to impact interactions with bacteria/virus at multiscale levels.

Self-assembly of glycoprotein nanostructured filaments for modulating extracellular networks at long range / Matassa, R.; Gatti, M.; Crociati, M.; Brunelli, R.; Battaglione, E.; Papi, M.; De Spirito, M.; Nottola, S. A.; Familiari, G.. - In: NANOSCALE. - ISSN 2040-3372. - 15:44(2023), pp. 17972-17986. [10.1039/d3nr02644b]

Self-assembly of glycoprotein nanostructured filaments for modulating extracellular networks at long range

Matassa R.
;
Gatti M.;Battaglione E.;De Spirito M.;Nottola S. A.;Familiari G.
2023

Abstract

The intriguing capability of branched glycoprotein filaments to change their hierarchical organization, mediated by external biophysical stimuli, continues to expand understanding of self-assembling strategies that can dynamically rearrange networks at long range. Previous research has explored the corresponding biological, physiological and genetic mechanisms, focusing on protein assemblies within a limited range of nanometric units. Using direct microscopy bio-imaging, we have determined the morpho-structural changes of self-assembled filament networks of the zona pellucida, revealing controlled levels of structured organizations to join distinct evolved stages of the oocyte (Immature, Mature, and Fertilized). This natural soft network reorganizes its corresponding hierarchical network to generate symmetric, asymmetric, and ultimately a state with the lowest asymmetry of the outer surface roughness, and internal pores reversibly changed from elliptical to circular configurations at the corresponding stages. These elusive morpho-structural changes are regulated by the nanostructured polymorphisms of the branched filaments by self-extension/-contraction/-bending processes, modulated by determinate theoretical angles among repetitive filament units. Controlling the nanoscale self-assembling properties by delivering a minimum number of activation bio-signals may be triggered by these specific nanostructured polymorphic organizations. Finally, this research aims to guide this soft biomaterial into a desired state to protect oocytes, eggs, and embryos during development, to favour/prevent the fertilization/polyspermy processes and eventually to impact interactions with bacteria/virus at multiscale levels.
2023
cytoskeleton; fertilization; glycoproteins; oocytes; zona pellucida; self assembly
01 Pubblicazione su rivista::01a Articolo in rivista
Self-assembly of glycoprotein nanostructured filaments for modulating extracellular networks at long range / Matassa, R.; Gatti, M.; Crociati, M.; Brunelli, R.; Battaglione, E.; Papi, M.; De Spirito, M.; Nottola, S. A.; Familiari, G.. - In: NANOSCALE. - ISSN 2040-3372. - 15:44(2023), pp. 17972-17986. [10.1039/d3nr02644b]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11573/1696745
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