posted on 2019-02-01, 00:00authored byAshit Rao, Teresa Roncal-Herrero, Elina Schmid, Markus Drechsler, Martin Scheffner, Denis Gebauer, Roland Kröger, Helmut Cölfen
Cellular
machineries guide the bottom-up pathways toward crystal
superstructures based on the transport of inorganic precursors and
their precise integration with organic frameworks. The biosynthesis
of mesocrystalline spines entails concerted interactions between biomolecules
and inorganic precursors; however, the bioinorganic interactions and
interfaces that regulate material form and growth as well as the selective
emergence of structural complexity in the form of nanostructured crystals
are not clear. By investigating mineral nucleation under the regulation
of recombinant proteins, we show that SpSM50, a matrix protein of
the sea urchin spine, stabilizes mineral precursors via vesicle-confinement,
a function conferred by a low-complexity, disordered region. Site-specific
proteolysis of this domain by a collagenase initiates phase transformation
of the confined mineral phase. The residual C-type lectin domain molds
the fluidic mineral precursor into hierarchical mesocrystals identical
to structural crystal modules constituting the biogenic mineral. Thus,
the regulatory functions of proteolytic enzymes can guide biomacromolecular
domain constitutions and interfaces, in turn determining inorganic
phase transformations toward hybrid materials as well as integrating
organic and inorganic components across hierarchical length scales.
Bearing striking resemblance to biogenic mineralization, these hybrid
materials recruit bioinorganic interactions which elegantly intertwine
nucleation and crystallization phenomena with biomolecular structural
dynamics, hence elucidating a long-sought key of how nature can orchestrate
complex biomineralization processes.