Structural and Functional Analyses of a Strong Chitin-Binding Protein-1 (SCBP-1) from the Exoskeleton of the Crayfish <i>Procambarus clarkii</i>

Cuticular proteins (crusticuls) affect 3D chitin bundle nanostructure

The crustacean exoskeleton features a micrometric, three-dimensional chitin scaffold. The intricate organization of this structure makes it an ideal model for investigating scaffold proteins at the nanoscale. Periodic exoskeleton replacement during a rapid and punctual molt cycle involves proteins that govern exoskeleton formation. Relying on binary expression pattern analysis of a molt-related transcriptomic library generated from the cuticle-forming epithelium of the crayfish Cherax quadricarinatus, a family of crustacean cuticle structural proteins termed 'crusticuls' was discovered and shown to present an exoskeleton formation-related expression pattern. All nine crusticuls include a chitin-binding domain bordered by two acidic residue-rich regions, putative functional domains related to exoskeletal formation and biomineralization. Crusticuls knock-down via RNAi resulted in over 95% reduced relative expression in treated versus control crayfish, with phenotypic effects ranging from prolonged molt cycles to lethality. Crusticuls were largely absent from newly formed cuticles following knockdown, resulting in exoskeletal deformities in the three-dimensional organization of chitinous bundles at the micro- and nanometric scales. These structural alterations were phenotypically translated into changes in cuticular hardness and elasticity. The identification of crusticuls as being key for proper nanometric three-dimensional organization of cuticular chitinous scaffolds opens new avenues for synthetic scaffold bio-mimetic applications.

PmCBP, a novel poly (chitin-binding domain) gene, participates in nacreous layer formation of Pinctada fucata martensii

Chitin participates in shell formation as the main component of an organic framework. Chitin-binding protein contains domains that can bind to chitin specifically. In this study, a novel chitin-binding protein from Pinctada fucata martensii (PmCBP) with poly (chitin-binding domain) was cloned, which contains a 5'-untranslated region (UTR) of 114 bp and 3'UTR of 116 bp, and encodes a putative protein of 2044 amino acids. The predicted PmCBP protein was structurally typical of the CBP family with 20 ChtBD2 domains. Phylogenetic and linear relation analyses showed that the ChtBD2 domain has a highly conserved structure among the three species of P. f. martensii, Crassostrea gigas, and Mizuhopecten yessoensis. qRT-PCR and in-situ hybridization analysis revealed that PmCBP was most abundant in the mantle pallium whose expression level was significantly correlated with the growth traits. After RNAi, PmCBP expression was significantly inhibited in the mantle pallium (P < 0.05) and the microstructure of nacreous layers showed a disordered growth in the experiment group. These results indicated that PmCBP may be involved in nacreous layer formation through participation in the process of binding chitin in pearl oyster P. f. martensii.

A crayfish molar tooth protein with putative mineralized exoskeletal chitinous matrix properties

Some crustaceans possess exoskeletons that are reinforced with calcium carbonate. In the crayfish Cherax quadricarinatus, the molar tooth, which is part of the mandibular exoskeleton, contains an unusual crystalline enamel-like apatite layer. As this layer resembles vertebrate enamel in composition and function, it offers an interesting example of convergent evolution. Unlike other parts of the crayfish exoskeleton, which is periodically shed and regenerated during the molt cycle, molar mineral deposition takes place during the pre-molt stage. The molar mineral composition transforms continuously from fluorapatite through amorphous calcium phosphate to amorphous calcium carbonate and is mounted on chitin. The process of crayfish molar formation is entirely extracellular and presumably controlled by proteins, lipids, polysaccharides, low-molecular weight molecules and calcium salts. We have identified a novel molar protein termed Cq-M15 from C. quadricarinatus and cloned its transcript from the molar-forming epithelium. Its transcript and differential expression were confirmed by a next-generation sequencing library. The predicted acidic pI of Cq-M15 suggests its possible involvement in mineral arrangement. Cq-M15 is expressed in several exoskeletal tissues at pre-molt and its silencing is lethal. Like other arthropod cuticular proteins, Cq-M15 possesses a chitin-binding Rebers-Riddiford domain, with a recombinant version of the protein found to bind chitin. Cq-M15 was also found to interact with calcium ions in a concentration-dependent manner. This latter property might make Cq-M15 useful for bone and dental regenerative efforts. We suggest that, in the molar tooth, this protein might be involved in calcium phosphate and/or carbonate precipitation.

A novel chitin binding crayfish molar tooth protein with elasticity properties

The molar tooth of the crayfish Cherax quadricarinatus is part of the mandible, and is covered by a layer of apatite (calcium phosphate). This tooth sheds and is regenerated during each molting cycle together with the rest of the exoskeleton. We discovered that molar calcification occurs at the pre-molt stage, unlike calcification of the rest of the new exoskeleton. We further identified a novel molar protein from C. quadricarinatus and cloned its transcript from the molar-forming epithelium. We termed this protein Cq-M13. The temporal level of transcription of Cq-M13 in an NGS library of molar-forming epithelium at different molt stages coincides with the assembly and mineralization pattern of the molar tooth. The predicted protein was found to be related to the pro-resilin family of cuticular proteins. Functionally, in vivo silencing of the transcript caused molt cycle delay and a recombinant version of the protein was found to bind chitin and exhibited elastic properties.

Identification and characterization of a matrix protein (PPP-10) in the periostracum of the pearl oyster, Pinctada fucata

The periostracum is a layered structure that is formed as a mollusk shell grows. The shell is covered by the periostracum, which consists of organic matrices that prevent decalcification of the shell. In the present study, we discovered the presence of chitin in the periostracum and identified a novel matrix protein, Pinctada fucata periostracum protein named PPP-10. It was purified from the sodium dodecyl sulfate/dithiothreitol-soluble fraction of the periostracum of the Japanese pearl oyster, P. fucata. The deduced amino acid sequence was determined by a combination of amino acid sequence analysis and cDNA cloning. The open reading frame encoded a precursor protein of 112 amino acid residues including a 21-residue signal peptide. The 91 residues following the signal peptide contained abundant Cys and Tyr residues. PPP-10 was expressed on the outer side of the outer fold in the mantle, indicating that PPP-10 was present in the second or third layer of the periostracum. We also determined that the recombinant PPP-10 had chitin-binding activity and could incorporate chitin into the scaffolds of the periostracum. These results shed light on the early steps in mollusk shell formation.

The molecular mechanism of calcification in aquatic organisms

Biomineralization is a process of mineral deposition by organisms. Calcium salts are the major component of various biominerals, calcium carbonate being the predominant type in aquatic organisms. The mechanism of biomineralization has been conventionally analyzed by microscopic observation. The findings obtained suggest that minute amounts of organic matrices in biominerals play a key role in biomineralization. We first introduced the methodology of bioactive compound chemistry into this research field. Using various biominerals, such as the exoskeleton and gastroliths of the crayfish, the otoliths and scales of fish, the coccoliths of coccolithophores, bivalve shells, and coral skeleton, a range of organic matrices were purified by simple functional assays, and their chemical structures were determined. The function of each matrix component was estimated by its ability to interact with calcium carbonate and by in vitro crystallization, immunological localization, and site-specific and temporal expression of the encoding genes in the case of proteins and peptides, among other compounds. It was found that there was almost no similarity in chemical structure among organic matrices from various biominerals, but similarity in function was observed, and that made possible the functional classification of organic matrices.