Your search keyword '"Malay AD"' showing total 6 results

1. Unusual p K a Values Mediate the Self-Assembly of Spider Dragline Silk Proteins.

Author

Oktaviani NA, Malay AD, Matsugami A, Hayashi F, and Numata K

Subjects

Animals, Silk chemistry, Dimerization, Magnetic Resonance Spectroscopy, Fibroins chemistry, Spiders metabolism

Abstract

Spider dragline silk is a remarkably tough biomaterial and composed primarily of spidroins MaSp1 and MaSp2. During fiber self-assembly, the spidroin N-terminal domains (NTDs) undergo rapid dimerization in response to a pH gradient. However, obtaining a detailed understanding of this mechanism has been hampered by a lack of direct evidence regarding the protonation states of key ionic residues. Here, we elucidated the solution structures of MaSp1 and MaSp2 NTDs from Trichonephila clavipes and determined the experimental p K a values of conserved residues involved in dimerization using NMR. Surprisingly, we found that the Asp40 located on an acidic cluster protonates at an unusually high pH (∼6.5-7.1), suggesting the first step in the pH response. Then, protonation of Glu119 and Glu79 follows, with p K a s above their intrinsic values, contributing toward stable dimer formation. We propose that exploiting the atypical p K a values is a strategy to achieve tight spatiotemporal control of spider silk self-assembly.

Published

2023

2. Complexity of Spider Dragline Silk.

Author

Malay AD, Craig HC, Chen J, Oktaviani NA, and Numata K

Subjects

Amino Acid Sequence, Animals, Recombinant Proteins chemistry, Recombinant Proteins genetics, Silk chemistry, Fibroins chemistry, Fibroins genetics, Spiders metabolism

Abstract

The tiny spider makes dragline silk fibers with unbeatable toughness, all under the most innocuous conditions. Scientists have persistently tried to emulate its natural silk spinning process using recombinant proteins with a view toward creating a new wave of smart materials, yet most efforts have fallen short of attaining the native fiber's excellent mechanical properties. One reason for these shortcomings may be that artificial spider silk systems tend to be overly simplified and may not sufficiently take into account the true complexity of the underlying protein sequences and of the multidimensional aspects of the natural self-assembly process that give rise to the hierarchically structured fibers. Here, we discuss recent findings regarding the material constituents of spider dragline silk, including novel spidroin subtypes, nonspidroin proteins, and possible involvement of post-translational modifications, which together suggest a complexity that transcends the two-component MaSp1/MaSp2 system. We subsequently consider insights into the spidroin domain functions, structures, and overall mechanisms for the rapid transition from disordered soluble protein into a highly organized fiber, including the possibility of viewing spider silk self-assembly through a framework relevant to biomolecular condensates. Finally, we consider the concept of "biomimetics" as it applies to artificial spider silk production with a focus on key practical aspects of design and evaluation that may hopefully inform efforts to more closely reproduce the remarkable structure and function of the native silk fiber using artificial methods.

Published

2022

3. Combination of Amorphous Silk Fiber Spinning and Postspinning Crystallization for Tough Regenerated Silk Fibers.

Author

Yazawa K, Malay AD, Ifuku N, Ishii T, Masunaga H, Hikima T, and Numata K

Subjects

Animals, Bombyx, Crystallization, Protein Structure, Secondary, Ethanol chemistry, Furans chemistry, Silk chemistry

Abstract

An artificial spinning system using regenerated silk fibroin solutions is adopted to produce high-performance silk fibers. In previous studies, alcohol-based agents, such as methanol or ethanol, were used to coagulate silk dope solutions, producing silk fiber with poor mechanical properties compared with those of native silk fibers. The alcohol-based coagulation agents induce rapid β-sheet crystallization of the silk molecules, which inhibits subsequent alignment of the β-sheet crystals. Here, we induce gradual β-sheet formation to afford adequate β-sheet alignment similar to that of native silk fiber. To this aim, we developed an amorphous silk fiber spinning process that prevents fast β-sheet formation in silk molecules by using tetrahydrofuran (THF) as a coagulation solvent. In addition, we apply postdrawing to the predominantly amorphous silk fibers to induce β-sheet formation and orientation. The resultant silk fibers showed a 2.5-fold higher extensibility, resulting in 1.5-fold tougher silk fibers compared with native Bombyx mori silk fiber. The amorphous silk fiber spinning process developed here will pave the way to the production of silk fibers with desired mechanical properties.

Published

2018

4. Liquid Crystalline Granules Align in a Hierarchical Structure To Produce Spider Dragline Microfibrils.

Author

Lin TY, Masunaga H, Sato R, Malay AD, Toyooka K, Hikima T, and Numata K

Subjects

Animals, Female, Fibroins ultrastructure, Liquid Crystals ultrastructure, Microfibrils ultrastructure, Microscopy, Atomic Force, Microscopy, Electron, Scanning, Fibroins chemistry, Liquid Crystals chemistry, Microfibrils chemistry, Spiders anatomy & histology

Abstract

The spider silk spinning process converts spidroins from an aqueous form to a tough fiber. This spinning process has been investigated by numerous researchers, and micelles or liquid crystals of spidroins have been reported to form silk fibers, which are bundles of silk microfibrils. However, the formation process of silk microfibrils has not been clarified previously. Here, we report that silk microfibrils are generated through the formation, homogenization, and linkage of liquid crystalline granules without micelle-like structures. Heterogeneous granules on the submicron to micron scale were observed in the storage sac, whereas homogeneous granules with diameters of approximately 100 nm were aligned along the tapering duct. In the spun fibers, the homogeneous granules were connected along the fiber axis. This is the first clear description of the formation of granule-based microfibrils in the spinning process, which is the key conversion process leading to the unique hierarchical structure of spider dragline.

Published

2017

5. Probing structural dynamics of an artificial protein cage using high-speed atomic force microscopy.

Author

Imamura M, Uchihashi T, Ando T, Leifert A, Simon U, Malay AD, and Heddle JG

Subjects

Microscopy, Atomic Force methods, Molecular Probes, Proteins chemistry

Abstract

A cysteine-substituted mutant of the ring-shaped protein TRAP (trp-RNA binding attenuation protein) can be induced to self-assemble into large, monodisperse hollow spherical cages in the presence of 1.4 nm diameter gold nanoparticles. In this study we use high-speed atomic force microscopy (HS-AFM) to probe the dynamics of the structural changes related to TRAP interactions with the gold nanoparticle as well as the disassembly of the cage structure. The dynamic aggregation of TRAP protein in the presence of gold nanoparticles was observed, including oligomeric rearrangements, consistent with a role for gold in mediating intermolecular disulfide bond formation. We were also able to observe that the TRAP-cage is composed of multiple, closely packed TRAP rings in an apparently regular arrangement. A potential role for inter-ring disulfide bonds in forming the TRAP-cage was shown by the fact that ring-ring interactions were reversed upon the addition of reducing agent dithiothreitol. A dramatic disassembly of TRAP-cages was observed using HS-AFM after the addition of dithiothreitol. To the best of our knowledge, this is the first report to show direct high-resolution imaging of the disassembly process of a large protein complex in real time.

Published

2015

6. Gold nanoparticle-induced formation of artificial protein capsids.

Author

Malay AD, Heddle JG, Tomita S, Iwasaki K, Miyazaki N, Sumitomo K, Yanagi H, Yamashita I, and Uraoka Y

Subjects

Catalysis, Models, Molecular, Particle Size, Protein Engineering, Surface Properties, Capsid chemistry, Gold chemistry, Metal Nanoparticles chemistry

Abstract

Gold nanoparticles are generally considered to be biologically inactive. However, in this study we show that the addition of 1.4 nm diameter gold nanoparticle induces the remodeling of the ring-shaped protein TRAP into a hollow, capsid-like configuration. This structural remodeling is dependent upon the presence of cysteine residues on the TRAP surface as well as the specific type of gold nanoparticle. The results reveal an apparent novel catalytic role of gold nanoparticles., (© 2012 American Chemical Society)

Published

2012