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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.

Introduction of a fluorine moiety into green fluorescent protein offers an interesting novel spectral variant. The calculated binding energy of fluorotyrosine (F-Tyr) (−8.42 kcal/mol) for tyrosyl tRNA synthetase was moderately higher than that of tyrosine (Tyr) (−8.36 kcal/mol). This result directly correlated with the expression level of F-Tyr containing GFP (38 mg/l), which was comparably higher than that of the parent GFP expression level (34 mg/l). Finally, we generated a model structure for GFP to assess possible interaction in the chromophore of the protein structure, which plays an important role in determining the spectral and folding behaviors of the F-Tyr incorporated GFP variant.

Recently, non-canonical amino acids (NCAA) incorporation was developed to enhance the functional properties of proteins. Incorporation of NCAA containing chlorine atom is conceptually an attractive approach to prepare pharmacologically active substances, which is a difficult task since chlorine is bulky atom. In this study, we evaluated the efficiency and extent of in vivo incorporation of tyrosine analogue 3-chlorotyrosine [(3-Cl)Tyr] into the recombinant proteins GFP and GFPHS (highly stable GFP). The incorporation of (3-Cl)Tyr into GFP leads to dramatic reduction in the expression level of protein. On the other hand, the incorporation of (3-Cl)Tyr into GFPHS was expressed well as a soluble form. In addition we used bioinformatics tools for the analysis to explore the possible constraints in micro-environment of each natural amino acid residue to be replaced with chlorine atom accommodation into GFPHS. In conclusion, our approaches are reliable and straightforward way to enhance the translation of chlorinated amino acids into proteins.

Alzheimer’s disease (AD) is a distressing neurodegenerative condition characterized by the accumulation of amyloid-beta (Aβ) plaques and tau tangles within the brain. The interconnectedness between membrane transporters (SLCs) and microRNAs (miRNAs) in AD pathogenesis has gained increasing attention. This review explores the localization, substrates, and functions of SLC transporters in the brain, emphasizing the roles of transporters for glutamate, glucose, nucleosides, and other essential compounds. The examination delves into the significance of SLCs in AD, their potential for drug development, and the intricate realm of miRNAs, encompassing their transcription, processing, functions, and regulation. MiRNAs have emerged as significant players in AD, including those associated with mitochondria and synapses. Furthermore, this review discusses the intriguing nexus of miRNAs targeting SLC transporters and their potential as therapeutic targets in AD. Finally, the review underscores the interaction between SLC transporters and miRNA regulation within the context of Alzheimer’s disease, underscoring the need for further research in this area. This comprehensive review aims to shed light on the complex mechanisms underlying the causation of AD and provides insights into potential therapeutic approaches.

In this study, we demonstrate the application of multiple functional properties of proteins generated through coupling of residue-specific and site-specific incorporation method. With green fluorescent protein (GFP) as a model protein, we constructed multifunctional GFP through sitespecific incorporation of L-3,4-dihydroxyphenylalanine (DOPA) and residue-specific incorporation of (2 S , 4 S )-4- fluoroproline (4 S -FP) or L-homopropargylglycine (hpg). Fluorescence analysis revealed a conjugation efficiency of approximately 20% for conjugation of DOPA-containing variants GFPdopa, GFPdp[4 S -FP], and GFPdphpg onto chitosan. While incorporation of 4 S -FP improved protein folding and stability, hpg incorporation into GFP allowed conjugation with fluorescent dye/polyethylene glycol (PEG). In addition, the modification of GFPhpg and GFPdphpg with PEG through Cu(I)-catalyzed click reaction increased protein thermal stability by about two-fold of the wild-type GFP.

In the past decade, numerous studies have been reported that the residue specific incorporation of fluorine containing analogs into protein can enhance the stability of protein. On the other hand, the incorporation of fluoroproline can enhance both stability and refolding rate of recombinant proteins. The objective of this study was to determine the reason behind the enhanced stability and refolding rate of protein by comparing GFP variants containing fluoroproline or hydroxyproline. The fluorine atom of 4-fluoroproline played a significant role in enhancing stability, and C γ - endo puckering property of (4 S )-4-fluoroproline and (4 S )-4-hydroxyproline plays a key role in enhancing protein refolding rate.

Genetically encoded fluorescent proteins are extensively utilized for labeling and imaging proteins, organelles, cell tissues, and whole organisms. In this study, we explored the feasibility of mRFP1 and its variants for measuring intracellular temperature. A linear relationship was observed between the temperature and fluorescence intensity of mRFP1 and its variants. Temperature sensitivities of E. coli expressing mRFP1, mRFP-P63A and mRFP-P63A[(4 R )-FP] were −1.27%, −1.26% and −0.77%/°C, respectively. Finally, we demonstrated the potentiality of mRFP1 and its variants as an in vivo temperature sensor.