Rufiat Nahar scite author profile

Rufiat Nahar

4Publications

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20Citation Statements Given

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Soka University

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Structural Analysis of Small G-Protein Ras Multimer Induced by Chemical Modification of HVR Domain with Caged Compound

Nahar

2021

Biophysical Journal

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Extracellular matrix mechanics influence diverse cellular functions, yet surprisingly little is known about the mechanical properties of their constituent collagens. While collagen type IV is an integral component of basement membranes, it has received far less attention than the more abundant fibrillar collagens. In this work, we used atomic force microscopy to image different collagen types and analyze their sequence-dependent mechanics. By analyzing their flexibility in a sequence-dependent manner, we learned that discontinuities in the triple-helix-defining sequence (Gly-X-Y) in collagen IV lead to a generally more flexible polymer with notable flexible ''hinges'' that correlate with non-helical regions. We contrast these findings

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Photoregulation of small G-protein RAS by the modification at HVR using azobenzene derivatives

Nahar

Alam

Alrazi

et al. 2022

Biophysical Journal

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Multimerization of small G-protein H-Ras induced by chemical modification at hyper variable region with caged compound

Nahar

Iwata

Morita

et al. 2021

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The lipid-anchored small G protein Ras is a central regulator of cellular signal transduction processes, thereby functioning as a molecular switch. Ras forms a nanocluster on the plasma membrane by modifying lipids in the hypervariable region (HVR) at the C-terminus to exhibit physiological functions. In this study, we demonstrated that chemical modification of cysteine residues in HVR with caged compounds (instead of lipidation) induces multimerization of H-Ras. The sulfhydryl-reactive caged compound, 2-nitrobenzyl bromide (NBB), was stoichiometrically incorporated into the cysteine residue of HVR and induced the formation of the Ras multimer. Light irradiation induced the elimination of the 2-nitrobenzyl group, resulting in the conversion of the multimer to a monomer. SEC-HPLC and small-angle X-ray scattering (SAXS) analysis revealed that H-Ras forms a pentamer. Electron microscopic observation of the multimer showed a circular ring shape, which is consistent with the structure estimated from X-ray scattering. The shape of the multimer may reflect the physiological state of Ras. It was suggested that the multimerization and monomerization of H-Ras were controlled by modification with a caged compound in HVR under light irradiation.

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Photocontrol of GTPase Cycle and Multimerization of the Small G-Protein H-Ras using Photochromic Azobenzene Derivatives

Nahar

Alrazi

et al. 2021

Biosci., Biotech. Res. Asia

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Ras is a small G protein known as a central regulator of cellular signal transduction that induces processes, such as cell division, transcription. The hypervariable region (HVR) is one of the functional parts of this G protein, which induces multimerization and interaction between Ras and the plasma membrane. We introduced two highly different in polarity photochromic SH group-reactive azobenzene derivatives, N-4-phenyl-azophenyl maleimide (PAM) and 4-chloroacetoamido-4-sulfo-azobenzene (CASAB), into three cysteine residues in HVR to control Ras GTPase using light. PAM stoichiometrically reacted with the SH group of cysteine residues and induced multimerization. The mutants modified with PAM exhibited reversible changes in GTPase activity accelerated by the guanine nucleotide exchange factor and GTPase activating protein and multimerization accompanied by cis- and trans-photoisomerization upon ultraviolet and visible light irradiation. CASAB was incorporated into two of the three cysteine residues in HVR but did not induce multimerization. The H-Ras GTPase modified with CASAB was photo controlled more effectively than PAM-H-Ras. In this study, we revealed that the incorporation of azobenzene derivatives into the functional site of HVR enables photo reversible control of Ras function. Our findings may contribute to the development of a method to control functional biomolecules with physiologically important roles.

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Rufiat Nahar

Structural Analysis of Small G-Protein Ras Multimer Induced by Chemical Modification of HVR Domain with Caged Compound

Photoregulation of small G-protein RAS by the modification at HVR using azobenzene derivatives

Multimerization of small G-protein H-Ras induced by chemical modification at hyper variable region with caged compound

Photocontrol of GTPase Cycle and Multimerization of the Small G-Protein H-Ras using Photochromic Azobenzene Derivatives

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