Jun Jie Loke scite author profile

Biomineralization, the process by which mineralized tissues grow and harden via biogenic mineral deposition, is a relatively lengthy process in many mineral-producing organisms, resulting in challenges to study the growth and biomineralization of complex hard mineralized tissues. Arthropods are ideal model organisms to study biomineralization because they regularly molt their exoskeletons and grow new ones in a relatively fast timescale, providing opportunities to track mineralization of entire tissues. Here, we monitored the biomineralization of the mantis shrimp dactyl club—a model bioapatite-based mineralized structure with exceptional mechanical properties—immediately after ecdysis until the formation of the fully functional club and unveil an unusual development mechanism. A flexible membrane initially folded within the club cavity expands to form the new club’s envelope. Mineralization proceeds inwards by mineral deposition from this membrane, which contains proteins regulating mineralization. Building a transcriptome of the club tissue and probing it with proteomic data, we identified and sequenced Club Mineralization Protein 1 (CMP-1), an abundant mildly phosphorylated protein from the flexible membrane suggested to be involved in calcium phosphate mineralization of the club, as indicated by in vitro studies using recombinant CMP-1. This work provides a comprehensive picture of the development of a complex hard tissue, from the secretion of its organic macromolecular template to the formation of the fully functional club.

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Integrative and comparative analysis of coiled-coil based marine snail egg cases – a model for biomimetic elastomers

Guerette

Tay

Hoon

et al. 2014

Biomater. Sci.

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Hierarchical Assembly of Tough Bioelastomeric Egg Capsules is Mediated by a Bundling Protein

et al. 2017

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Marine snail egg capsules are shock-absorbing bioelastomers made from precursor "egg case proteins" (ECPs) that initially lack long-range order. During capsule formation, these proteins self-assemble into coiled-coil filaments that subsequently align into microscopic layers, a multiscale process which is crucial to the capsules' shock-absorbing properties. In this study, we show that the self-assembly of ECPs into their functional capsule material is mediated by a bundling protein that facilitates the aggregation of coiled-coil building blocks and their gelation into a prefinal capsule prior to final stabilization. This low molecular weight bundling protein, termed Pugilina cochlidium Bundling Protein (PcBP), led to gelation of native extracts from gravid snails, whereas crude extracts lacking PcBP did not gelate and remained as a protein solution. Refolding and reconcentration of recombinant PcBP induced bundling and aggregation of ECPs, as evidenced by ECPs oligomerization. We propose that the secretion of PcBP in vivo is a time-specific event during the embryo encapsulation process prior to cross-linking in the ventral pedal gland (VPG). Using molecular dynamics (MD) simulations, we further propose plausible disulfide binding sites stabilizing two PcBP monomers, as well as a polarized surface charge distribution, which we suggest plays an important role in the bundling mechanism. Overall, this study shows that controlled bundling is a key step during the extra-cellular self-assembly of egg capsules, which has previously been overlooked.

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Biomimetic photonic coatings using squid reflectin protein

Loke¹

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Characterisation of a bundling protein involved in the self-assembly of bioelastomeric snail egg cases

Loke¹

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The carnivorous marine snail Pugilina cochlidium is found predominantly on the sea shores of the South-East Asia region. This sea creature lays a string of egg capsules up to a metre in length which houses its embryos. The egg capsule material must be able to withstand and resist the harsh and relentless tidal forces of the ocean in order for the off-springs to develop properly and survive.The egg capsule was found to be made up of egg capsule protein precursors which domains are predominately filamentous made of coiled-coils. Four laminar protein sheets were also found to be oriented perpendicular to each other. Mechanical V Volts xg Centrifugal gravitational force βME 2-Mercaptoethanol, Beta-Mercaptoethanol

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Jun Jie Loke

A diecast mineralization process forms the tough mantis shrimp dactyl club

Integrative and comparative analysis of coiled-coil based marine snail egg cases – a model for biomimetic elastomers

Hierarchical Assembly of Tough Bioelastomeric Egg Capsules is Mediated by a Bundling Protein

Biomimetic photonic coatings using squid reflectin protein

Characterisation of a bundling protein involved in the self-assembly of bioelastomeric snail egg cases

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