Abstract
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.
Highlights
Ras is a small G protein known as a central regulator of cellular signal transduction that induces processes, such as cell division, transcription
The mutants modified with phenyl-azophenyl maleimide (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
The three cysteine residues in the hypervariable region (HVR) of H-Ras mutants were almost stoichiometrically modified by PAM (Cys residues in HVR:PAM = 3.0:3.2)
Summary
Ras is a small G protein known as a central regulator of cellular signal transduction that induces processes, such as cell division, transcription. 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. Conformational changes in the HVR determine the physiological performance of Ras. We have recently demonstrated that chemical modification of the cysteine residues in the HVR of Ras with SH group-reactive caged compounds instead of lipidation induces multimerization of Ras, which may mimic the physical cluster structure 11. The results suggested that incorporating a specific group into the HVR lipidation site may induce artificial physiological structural changes related to Ras function. We utilized an azobenzene derivative as a photoreversible nano-switching device and incorporated it into the HVR to control Ras function.
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