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Abstract
Silicateins play a key role in biosynthesis of spicules in marine sponges; they are also capable to catalyze formation of amorphous silica in vitro. Silicateins are highly homologous to cathepsins L – a family of cysteine proteases. Molecular mechanisms of silicatein activity remain controversial. Here site-directed mutagenesis was used to clarify significance of selected residues in silica polymerization. A number of mutations were introduced into two sponge proteins – silicatein A1 and cathepsin L from Latrunculia oparinae, as well as into human cathepsin L. First direction was alanine scanning of the proposed catalytic residues. Also, reciprocal mutations were introduced at selected positions that differ between cathepsins L and silicateins. Surprisingly, all the wild type and mutant proteins were capable to catalyze amorphous silica formation with a water-soluble silica precursor tetra(glycerol)orthosilicate. Some mutants possessed several-fold enhanced silica-forming activity and can potentially be useful for nanomaterial synthesis applications. Our findings contradict to the previously suggested mechanisms of silicatein action via a catalytic triad analogous to that in cathepsins L. Instead, a surface-templated biosilification by silicateins and related proteins can be proposed.
Highlights
Silicateins are the common spicule-forming proteins of marine sponges[1]
Due to high protein similarity the same conditions were used for cathepsin L (CTSL), but it was found that this protein should be expressed on 25 °C after induction
In the present work we found that CTSL possesses silicatein-like activity and catalyzes silica polymerization
Summary
Silicateins are the common spicule-forming proteins of marine sponges[1]. They are homologous to cathepsins – a family of proteases acting mainly in lysosomes at the low pH2. The data showed that both LoSilA1 and LoCath form similar amorphous silica particles with TGS (Fig. 3). Y27W substitution was introduced because this flanking residue is conservative in all the silica-condensing proteins, but differs in CTSL (Fig. 4). All the mutants demonstrated silica polymerizing activity, even proteins with alanine in the active site (Fig. 5).
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